-
1 melting through
Строительство: проплавка на всю толщину, проплавляющий на всю толщину -
2 melting through
przetapianie -
3 melting-through
метал. -
4 cupola melting
-
5 destruction of floating ice through melting
Универсальный англо-русский словарь > destruction of floating ice through melting
-
6 figures formed in ice crystals through internal melting by absorbed radiation
Макаров: фигуры, возникающие в ледяных кристаллах при внутреннем плавлении за счёт поглощаемой лучистой энергииУниверсальный англо-русский словарь > figures formed in ice crystals through internal melting by absorbed radiation
-
7 loss of a glacier mass through evaporation and melting with runoff
Универсальный англо-русский словарь > loss of a glacier mass through evaporation and melting with runoff
-
8 lower part of a glacier where its mass is annually diminished through melting and evaporation of snow and ice
Макаров: нижняя часть ледника, где в течение балансового года его масса уменьшается вследствие таяния и испарения снега и льдаУниверсальный англо-русский словарь > lower part of a glacier where its mass is annually diminished through melting and evaporation of snow and ice
-
9 thin ice formed on the surface of water accumulated on older floating ice due to its melting or issuing from under the ice through cracks
Общая лексика: тонкий лед, образовавшийся на воде, скопившейся на более старом плавучем льду при таянии или выступившей из-подУниверсальный англо-русский словарь > thin ice formed on the surface of water accumulated on older floating ice due to its melting or issuing from under the ice through cracks
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10 zone on a glacier where melting embraces less than 10% of snow deposited through the year and ice formation is mainly due to snow settling and recrystallization
Общая лексика: зона на леднике, где таяние охватывает менее 10% отложенного за год снега и льдообразоваУниверсальный англо-русский словарь > zone on a glacier where melting embraces less than 10% of snow deposited through the year and ice formation is mainly due to snow settling and recrystallization
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11 furnace
1) печь2) топка, топочная камера5) термостат ( в хроматографии)•-
anode-drop furnace
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Pulse furnace
-
acid furnace
-
acid open-hearth furnace
-
air furnace
-
air tempering furnace
-
Ajax furnace
-
all-basic furnace
-
all-electric furnace
-
all-radiant furnace
-
annealing furnace
-
annular furnace
-
arc furnace
-
ash fusion furnace
-
asphalt furnace
-
assay furnace
-
bakeout furnace
-
barrel-type furnace
-
basic furnace
-
basic open-hearth furnace
-
basic oxygen furnace
-
batch-type furnace
-
batch furnace
-
bath-type furnace
-
bath furnace
-
bell-type furnace
-
belt furnace
-
belt-charged blast furnace
-
belt-heating furnace
-
bifurcated furnace
-
biscuit furnace
-
black furnace
-
blackening furnace
-
blast furnace
-
bogie hearth furnace
-
bogie furnace
-
bogie-type furnace
-
boiler furnace
-
boosted furnace
-
bottom-electrode arc furnace
-
bottom-fired walking-beam furnace
-
box furnace
-
brick furnace
-
bung-type roof furnace
-
burnout furnace
-
calcining furnace
-
car furnace
-
carborundum furnace
-
carburizing furnace
-
catalyst furnace
-
catenary arch furnace
-
catenary furnace
-
cathode-ray furnace
-
cellulating furnace
-
ceramic furnace
-
chamber furnace
-
channel-gasification furnace
-
circular furnace
-
closed-top furnace
-
coal-fired furnace
-
coil-heating furnace
-
coiling furnace
-
cold top furnace
-
cold-charged furnace
-
combined direct flame-radiant tube furnace
-
compartment furnace
-
consumable electrode arc furnace
-
continuous annealing furnace
-
continuous furnace
-
continuous pack-and-pair heating furnace
-
continuous single-strand furnace
-
conveyortype furnace
-
conveyor furnace
-
copper blast furnace
-
copper-smelting furnace
-
coreless-type induction furnace
-
coreless induction furnace
-
core-type induction furnace
-
corner-fired furnace
-
cracking furnace
-
cross-fired furnace
-
crucible furnace
-
crucible melting furnace
-
crystal growing furnace
-
crystal-pulling furnace
-
cupelling furnace
-
cupel furnace
-
cupola furnace
-
cyaniding furnace
-
cyclone furnace
-
descaling furnace
-
devitrification furnace
-
diffusion furnace
-
direct resistance furnace
-
direct-arc conducting hearth furnace
-
direct-arc furnace
-
direct-fired furnace
-
direct-fired reducing furnace
-
divided furnace
-
double-bed furnace
-
double-crown furnace
-
double-end fired furnace
-
double-hearth furnace
-
down-draft furnace
-
downshot-type furnace
-
downward-fired furnace
-
drip furnace
-
dry-bottom furnace
-
dry furnace
-
EB furnace
-
electric furnace
-
electric pig-iron furnace
-
electric pit-type heating furnace
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electric resistance furnace
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electric steel furnace
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electric-tube furnace
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electrode-hearth arc furnace
-
electrolytic furnace
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electron beam furnace
-
electroslag remelting furnace
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enameling furnace
-
enamel furnace
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end-fired furnace
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epitaxial furnace
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equalizing furnace
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equiflux furnace
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fagoted iron furnace
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ferroalloy furnace
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fired top and bottom furnace
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firing furnace
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fixed furnace
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fixed open-hearth furnace
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fixed roof-type furnace
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flame furnace
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flash furnace
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flat glass furnace
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flattening furnace
-
fluid-bed furnace
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forging furnace
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Fourcault tank furnace
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frit furnace
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front-door furnace
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front-fired furnace
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gantry-type furnace
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garbage furnace
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gas chamber furnace
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gas furnace
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gas-fired radiant tube furnace
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gas-reforming furnace
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glass furnace
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glass-bending furnace
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glass-foam furnace
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glass-melting furnace
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glazing furnace
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gradient furnace
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graphite rod melting furnace
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hand-rabbled furnace
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hardening furnace
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hearth furnace
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heating furnace
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heat-treatment furnace
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Heroult electric arc furnace
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high-frequency furnace
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high-frequency induction furnace
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high-frequency steel furnace
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high-temperature solar furnace
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high-top pressure blast furnace
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holding furnace
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holding-melting furnace
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hood-type annealing furnace
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horizontal ring furnace
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hot air furnace
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ignition furnace
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immersed electrode salt-bath furnace
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immersion-burner furnace
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immersion furnace
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in-and-out furnace
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independent-arc furnace
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indirect resistance furnace
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indirect-arc furnace
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induction crucible furnace
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induction low-frequency furnace
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induction melting furnace
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induction-arc furnace
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induction furnace
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induction-stirred furnace
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ingot heating furnace
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iron-and-steel furnaces
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iron-melting furnace
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LD furnace
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lift-and-swing-aside roof furnace
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lift-coil induction furnace
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lift-off bell-type furnace
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lift-off bell furnace
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liquid-ball furnace
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low-frequency furnace
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low-shaft furnace
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low-thermal mass furnace
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Maerz-Boelens furnace
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malleable annealing furnace
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Martin furnace
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matting furnace
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mechanically rabbled furnace
-
melting furnace
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mesh belt conveyor furnace
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Miguet furnace
-
moving belt furnace
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muffle furnace
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multiple-bedded furnace
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multistack annealing furnace
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multistage furnace
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nitriding furnace
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nonferrous melting furnace
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nonoxidizing annealing furnace
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normalizing furnace
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oil-fired furnace
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one-zone furnace
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open gas furnace
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open-flame furnace
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open-hearth furnace
-
open-hearth rolling furnace
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open-top furnace
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opposed-firing furnace
-
ore furnace
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ore-smelting furnace
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overburdened furnace
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oxidation furnace
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permeable-lining furnace
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petroleum furnace
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pipe furnace
-
pit-type furnace
-
pit furnace
-
plasmarc furnace
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plate-glass furnace
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plate furnace
-
porcelain-enamel furnace
-
positive pressure furnace
-
pot furnace
-
pot-and-muffle furnace
-
preheating furnace
-
pressure-fired furnace
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printing furnace
-
producer furnace
-
protective gas furnace
-
pulverized-coal dry-ash furnace
-
pulverized-coal furnace
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pulverized-coal slag-tap furnace
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pusher-type furnace
-
pusher furnace
-
quartz-melting furnace
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quartz furnace
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quenching furnace
-
rabbling furnace
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radiant tubular furnace
-
radiation furnace
-
reaction furnace
-
recirculation forced convection furnace
-
recirculation furnace
-
rectangular hood furnace
-
recuperative continuous furnace
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recuperative furnace
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refining furnace
-
reforming furnace
-
regenerative furnace
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removable cover furnace
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resistance arc furnace
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resistance element salt-bath furnace
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resistance furnace
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resistance tube furnace
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resistance-heated pot-type furnace
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resistance-heating muffle furnace
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resistor furnace
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resistor melting furnace
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reverberating furnace
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ring furnace
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roasting furnace
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rocking arc furnace
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rocking furnace
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rocking resistor furnace
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Rohn furnace
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roller-hearth furnace
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roof lance furnace
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rotary hearth furnace
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rotating-bath furnace
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rotor furnace
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runout-body furnace
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salt furnace
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sealed quench furnace
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self-powered furnace
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semirotary melting furnace
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shaft furnace
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shaft-coking furnace
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sheet-glass furnace
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sheet furnace
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shelf furnace
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short annealing furnace
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side-charged furnace
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side-port furnace
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singeing furnace
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single furnace
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single pot furnace
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single-cell furnace
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single-stack annealing furnace
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sintering furnace
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sinter furnace
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skull furnace
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slag-drip furnace
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slagging-bottom furnace
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slag-tap furnace
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sloping hearth furnace
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smelting furnace
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solar furnace
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soldering furnace
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Solvex cracking furnace
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spark-gap converter furnace
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stationary open-hearth furnace
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steel-making furnace
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steel furnace
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strand-type furnace
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stress-relieving furnace
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submerged-arc furnace
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supercharged furnace
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sweat furnace
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symmetric LD furnace
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tandem furnace
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tangentially fired furnace
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tank furnace
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three-cell furnace
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three-phase ore-smelting furnace
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three-storied furnace
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through-type retort furnace
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tile furnace
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tilling furnace
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tilting open-hearth furnace
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tipping furnace
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top hat annealing furnace
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top-charge furnace
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top-fired heating furnace
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toughening furnace
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tower-type furnace
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traveling hearth furnace
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triple-bell furnace
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triple-fired furnace
-
tube furnace
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twin furnace
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underfeed furnace
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upshot fired furnace
-
upshot furnace
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vacuum furnace
-
vacuum-arc-refining furnace
-
vacuum-induction furnace
-
versatile bar furnace
-
vertical pull-through furnace
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VIM furnace
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walking beam furnace
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warm-air furnace
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water-cooled furnace
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water-cooled infrared furnace
-
water-jacketed furnace
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water-jacket furnace
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water-walled furnace
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wet-bottom furnace
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wind furnace
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zinc-distillation furnace
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zone melting furnace -
12 melt
1. intransitive verb1) schmelzen; (dissolve) sich auflösen2. transitive verbmelt in one's or the mouth — (coll.) auf der Zunge zergehen; see also academic.ru/9865/butter">butter 1.
2) (fig.): (make tender) erweichen [Person, Herz]Phrasal Verbs:* * *[melt](to (cause to) become soft or liquid, or to lose shape, usually by heating / being heated: The ice has melted; My heart melted when I saw how sorry he was.) schmelzen- meltdown- melting-point
- melting pot* * *[melt]I. nII. vi1. (turn into liquid) schmelzento \melt in the mouth auf der Zunge zergehenhe only has to look at her and she \melts er braucht sie nur anzusehen, und schon schmilzt sie dahin3. ( fig)▪ to \melt into sth (change gradually) in etw akk übergehen; (disappear) sich akk in etw dat auflösento \melt into the background sich akk in den Hintergrund zurückziehenIII. vt▪ to \melt sth etw schmelzenthe sun \melted the snow der Schnee schmolz in der Sonneto \melt sb [or sb's heart] jdn erweichen* * *[melt]1. vt1) (lit) schmelzen; snow schmelzen, zum Schmelzen bringen; butter zergehen lassen, zerlassen; sugar, grease auflösen2. viit just melts in the mouth — es zergeht einem nur so auf der Zunge
... and then his heart melted —... und dann ließ er sich erweichen
* * *melt [melt]A v/i1. (zer)schmelzen, flüssig werden, sich auflösen, zergehen:melt away wegschmelzen;melt down zerfließen;melt through durchschmelzen;melt in the mouth auf der Zunge zergehen;3. zusammenschrumpfenwith vor dat):melt into tears in Tränen zerfließen5. fig auftauen, weich werden, schmelzen (Herz, Mensch)6. BIBEL verzagen7. verschmelzen, verschwimmen, ineinander übergehen (Ränder, Farben etc):melt into übergehen in (akk);outlines melting into each other verschwimmende Umrisse9. hum vor Hitze vergehen, zerfließenB v/t1. schmelzen, zum Schmelzen bringen3. TECH schmelzen:melt down nieder-, einschmelzen;melt out ausschmelzen4. fig jemandes Herz erweichen, rührenC s1. METALL Schmelzen n2. Schmelze f, geschmolzene Masse* * *1. intransitive verb1) schmelzen; (dissolve) sich auflösen2. transitive verbmelt in one's or the mouth — (coll.) auf der Zunge zergehen; see also butter 1.
2) (fig.): (make tender) erweichen [Person, Herz]Phrasal Verbs:* * *v.erweichen v.rühren v.schmelzen v.(§ p.,pp.: schmolz, ist/hat geschmolzen)zergehen v. -
13 point
1) точка2) остриё, острый конец || заострять4) положение; позиция; координата ( рабочего органа)5) указывать; ориентировать, наводить6) место; пункт11) ж.-д. стрелочный перевод; стрелка; остряк, перо ( стрелочного перевода)13) расшивать швы ( кладки)16) пишущий узел, пишущий элемент (ручки, карандаша)17) пищ. оценочный балл•point at infinity — бесконечно удалённая точка;to point off — отводить ( в сторону);to pass through a point — проходить через точку-
Abel flash point
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acid dew point
-
actual point
-
acute round needle point
-
addressable point
-
adherent point
-
aerodrome check point
-
aerodrome reference point
-
agate arrestment point
-
aggregative transition point
-
agreed reporting point
-
aiming point
-
air supply breathing point
-
aircraft fire point
-
alternator pivot point
-
anchor point
-
anchorage point
-
aniline point
-
annealing point
-
antinodal point
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aplantic points
-
arch work point
-
arithmetic point
-
array feed point
-
assumed point
-
attachment point
-
automatic point
-
azeotropic point
-
backoff point
-
backward stagnation point
-
balance point
-
base point
-
bend point
-
bending yield point
-
binary point
-
bleeding point
-
bleed point
-
blow point
-
blunt round needle point
-
boiling point
-
boundary point
-
branch point
-
breaker point
-
break-in point
-
breaking point
-
brittle point
-
bubble point
-
bucking point
-
bullet point
-
burble point
-
burn point
-
burning point
-
burnout point
-
burster point
-
cardinal points
-
casing point
-
central point
-
changeover point
-
characteristic point
-
check point
-
chemical-pinch point
-
chilling point
-
chisel point
-
clearing point
-
close spread collar point
-
closed flash point
-
cloud point
-
cold point
-
collinear points
-
collocation point
-
common depth point
-
compass points
-
concyclic points
-
condensation point
-
congelation point
-
consolute point
-
consumption point of current
-
contact point
-
contactor points
-
control point
-
control transfer point
-
corona point
-
correct point
-
coupler pivot point
-
coupling point
-
critical point
-
crossing point
-
crossover point
-
cryogen boiling point
-
Curie point
-
cuspidal point
-
cut point
-
cutoff point
-
cutting point
-
datum point
-
dead point
-
decimal point
-
defined point
-
delivery point
-
demixing point
-
dendritic point
-
depth reference point
-
destination point
-
destruction point
-
detonation point
-
dew point
-
dial indicator contact point
-
diamond grinding point
-
diamond point
-
directional kickoff point
-
discharge point
-
dispatching point
-
dispersion point
-
distinct curve collar point
-
distinct points
-
distinguished point
-
distribution point
-
double point
-
drain point
-
draw point
-
drawoff point
-
driving point
-
dropping point
-
dry point
-
dryout point
-
early warning point
-
edit point
-
edit-in point
-
edit-out point
-
elevation point
-
elliptic point
-
emission point
-
end point
-
energy breakeven point
-
entry point
-
entry-exit points
-
equal time point
-
equilibrium point
-
eutectic point
-
exclamation point
-
exhaustion end point
-
exit point
-
exterior point
-
extraction point
-
face point
-
fashioning point
-
fatigue point
-
feeding point
-
fiber saturation point
-
fiducial point
-
filling point
-
filling-in point
-
film entry point
-
film leaving point
-
final approach point
-
final boiling point
-
fine point
-
fire point
-
firing point
-
fixed point
-
flame break point
-
flare point
-
flash point
-
flexion point
-
flight reference point
-
flight way point
-
floating point
-
floc point
-
flooding point
-
flow point
-
flywheel dead point
-
focal point
-
forced open point
-
forward stagnation point
-
fouling point
-
freeze point
-
freezing point
-
French point
-
frontier point
-
frost point
-
fuel injection point
-
fuel servicing point
-
full point
-
fusing point
-
gage point
-
gaging point
-
gas hydrate formation point
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gas point
-
geodetic point
-
glazier's point
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gloss point
-
grasp point
-
grid point
-
grouped service points
-
half point
-
hammer point
-
hard points
-
heat point
-
heavy ball needle point
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heavy rounded set needle point
-
heavy set needle point
-
holding point
-
hopper work point
-
horizontal control point
-
ice point
-
ignition point
-
image point
-
impact point
-
incongruent melting point
-
index point
-
infeed changeover point
-
initial point
-
injection point
-
insertion point
-
integral point
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intended landing point
-
intercardinal point
-
interception point
-
intercept point
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interior point
-
interlocked point
-
isoelectric point
-
jacking point
-
junction point
-
knee point
-
laminar separation point
-
landfall point of the storm
-
last departure point
-
lattice point
-
leaving point
-
leveling point
-
level point
-
lifter point
-
lifting point
-
lift-off point
-
light ball needle point
-
light rounded set needle point
-
light set needle point
-
limiting point
-
limit point
-
linking point
-
load point
-
loading point
-
load-unload point
-
long collar point
-
lower yield point
-
lubrication point
-
machine home point
-
macroyield point
-
maker point
-
matching point
-
matrix point
-
maximum power point
-
measurement point
-
measure point
-
medium ball needle point
-
melting point
-
mesh point
-
mid-boiling point
-
mixed melting point
-
movable point
-
multiple point
-
needle point
-
neutral point
-
nodal point
-
node point
-
noise measurement point
-
normal round needle point
-
observation point
-
open point
-
operation point
-
optimum point
-
panel point
-
paper point
-
paraffin crystallization point
-
peak point
-
pelerine point
-
pen point
-
pickup point
-
piercing point
-
pile stoppage point
-
pinch point
-
pinning point
-
pitch point
-
pivotal point
-
pivot point
-
plait point
-
plow point
-
point of absolute zero
-
point of arrival
-
point of contraflexure
-
point of curve
-
point of departure
-
point of discontinuity
-
point of distance
-
point of engagement
-
point of fault
-
point of force application
-
point of graph
-
point of hook
-
point of increase
-
point of inflection
-
point of intersection
-
point of load application
-
point of looper
-
point of maximum
-
point of minimum
-
point of no return
-
point of occlusion
-
point of sight
-
point of support
-
point of tangency
-
point of tree
-
porous point
-
pour point
-
power point
-
precision point
-
preroll point
-
primary calibration point
-
principal point
-
probe point
-
projected peak point
-
pullout point
-
quadrantal point
-
quarter-span point
-
quarter point
-
quiescent operating point
-
radix point
-
reaction point
-
receiving point
-
reentry point
-
reference point
-
reflection depth point
-
refraction depth point
-
regional heat point
-
reporting point
-
rerun point
-
ripper point
-
rounded set needle point
-
saddle point
-
salient point
-
saturation point
-
sectioning point
-
set needle point
-
set point
-
setting point
-
shot point
-
sighting point
-
singing point
-
single defect point
-
single point
-
singular point
-
sintering point
-
slinging point
-
smoke point
-
softening point
-
solder termination point
-
solidification point
-
source point
-
special ball needle point
-
spring point
-
square collar point
-
stable point
-
stadia point
-
stagnation point
-
star point
-
stationary breaker point
-
stitch transfer point
-
stuck point
-
subsatellite point
-
support point
-
surveying point
-
survey point
-
switch point
-
switching point
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takeoff point
-
tangent point
-
tapping point
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terminal point
-
termination point
-
test point
-
thaw point
-
thermal critical point
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thermodynamic point
-
third point
-
threshold point
-
tie point
-
toll point
-
tool point
-
touch point
-
touchdown point
-
towing point
-
tow point
-
trailing point
-
transfer initiation point
-
transfer point
-
transformation point
-
transit point
-
transition point
-
trap point
-
triangulation point
-
triple point
-
tripping point
-
true molal boiling point
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turning point
-
umbilical point
-
unload point
-
unloading point
-
upper yield point
-
valley point
-
vanishing point
-
vertical control point
-
visible point
-
vitrifying point
-
volumetric boiling point
-
water supply point
-
wax dropout point
-
weight boiling point
-
weight-drop point
-
well point
-
wiring point
-
word break point
-
working point
-
yield point
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Y-point
-
zero point -
14 technique
2) технология; (технологический) приём3) алгоритм4) оборудование; технические средства; техника•-
active neutron technique
-
Afmag technique
-
airborne technique
-
air-conditioning technique
-
alignment technique
-
alloy-diffusion technique
-
anchoring technique
-
angled-lapping technique
-
angle-lapping technique
-
angled-lap technique
-
angle-lap technique
-
apertured-detector technique
-
arc-melting technique
-
assembly technique
-
audio record cutting technique
-
audio-frequency magnetic technique
-
batch-fabrication technique
-
batch technique
-
beam-lead microcircuit technique
-
birefringent coating technique
-
bonding technique
-
brittle coating technique
-
broadside technique
-
BTR technique
-
carbon extraction technique
-
cementing technique
-
check summation technique
-
check sum technique
-
chemiluminescence technique
-
cine technique
-
circuit technique
-
CM technique
-
collector-diffusion isolation technique
-
computer simulation techniques
-
computing technique
-
conformable masking technique
-
coring technique
-
cryogenic technique
-
crystal growth technique
-
crystal-pulling technique
-
curing technique
-
curve-fitting technique
-
Czochralski growth technique
-
Czochralski technique
-
decoration technique
-
design technique
-
destructive inspection technique
-
diffusion technique
-
direct writing technique
-
diversity technique
-
doping technique
-
dot-and-dash technique
-
double-specimen technique
-
double-theodolite technique
-
drilling technique
-
dry etching technique
-
dry etch technique
-
echo-sounding technique
-
editing technique
-
electrodeless technique
-
electron channeling technique
-
electron-ion storage technique
-
electroplating technique
-
encapsulation technique
-
energy conservation technique
-
energy conversion technique
-
epitaxial growth technique
-
epitaxial technique
-
etching technique
-
etch technique
-
evaporation technique
-
expanding-spread technique
-
fabrication technique
-
face-down technique
-
Fane knit technique
-
figure-of-eight technique
-
film technique
-
film-carrier technique
-
fine-line technique
-
fixed-abrasive machining technique
-
flip-chip technique
-
floating-zone technique
-
float-zone technique
-
floating-charge technique
-
flood routing technique
-
fluidization technique
-
folded-spectrum technique
-
forecasting technique
-
fracture replica technique
-
freezing technique
-
gamma-ray technique
-
geomagnetic induction technique
-
graphical design technique
-
gravity anchoring technique
-
growing technique
-
head space technique
-
heat pulse technique
-
heuristic technique
-
high-speed motion-picture technique
-
high-tech machining technique
-
high-vacuum technique
-
high-voltage technique
-
high-voltage testing technique
-
high-voltage test technique
-
holographic technique
-
horizontal stacking technique
-
hyperflow technique
-
imaging technique
-
in-cycle gaging technique
-
infrared nondestructive technique
-
in-process gaging technique
-
integrated-circuit technique
-
integrated technique
-
interconnection technique
-
interference technique
-
ion implantation technique
-
ion-exchange technique
-
isolation technique
-
isotope correlation technique
-
job setting technique
-
junction isolation technique
-
ladle-degassing technique
-
layout technique
-
lift-off technique
-
lithographic technique
-
long-hole technique
-
loose-abrasive machining technique
-
manufacturing technique
-
mask technique
-
masking technique
-
mass-flow technique
-
mass-spectrometric technique
-
matrix technique
-
microalloy technique
-
microelectronic technique
-
microfabrication technique
-
microprobe technique
-
microscopic technique
-
microstructure fabrication technique
-
microstructure technique
-
mid-depth tow technique
-
motion-picture technique
-
mounting technique
-
multicamera technique
-
multichip bonding technique
-
multiple seismometer technique
-
multiple-access technique
-
near-bottom tow technique
-
nondestructive inspection technique
-
normal-freezing technique
-
observing technique
-
optimizing technique
-
ordered elimination technique
-
overlay technique
-
packaging technique
-
parallel-line technique
-
parts classification technique
-
pattern recognition technique
-
pattern-defining technique
-
phase separation and leaching technique
-
photoelastic technique
-
photofinishing technique
-
photographic technique
-
photolithographic technique
-
photoprocessing technique
-
photoresist-processing technique
-
piled anchoring technique
-
piled/gravity anchoring technique
-
pilot technique
-
potential-drop-ratio technique
-
preferential etching technique
-
preferential etch technique
-
printed-circuit technique
-
probe technique
-
processing technique
-
production technique
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program production technique
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programming technique
-
projection technique
-
pulse-echo technique
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pyrometric technique
-
radioactive tracer technique
-
radio-echo technique
-
ramp assisted toil casting technique
-
refrigeration technique
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registration technique
-
reocasting technique
-
replica technique
-
river-basin simulation technique
-
robotic handling techniques
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roll-and-scroll technique
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roll technique
-
round-robin technique
-
screen-printing technique
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selective ion etching technique
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selective ion etch technique
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self-synchronization technique
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side-wall neutron technique
-
silk-screening technique
-
simulation technique
-
spill-cleaning technique
-
spin-on technique
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sputtering technique
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stimulation technique
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strain anneal technique
-
structural arrest technique
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suction anchoring technique
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surface passivation technique
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tape-automated-bonding technique
-
technique of directional crystallization
-
technique of mold reciprocation
-
television production technique
-
television technique
-
testing technique
-
thermocompression technique
-
through-flow line servicing technique
-
time-lapse technique
-
touch trigger probing technique
-
tribometric technique
-
two-point technique
-
ultrahigh-vacuum technique
-
unmanned production technique
-
vacuum technique
-
vapor-phase epitaxial technique
-
vertical crystal pulling technique
-
vertical pulling technique
-
video tape editing technique
-
voltage balancing technique
-
water allocation technique
-
water injection-fume exhaustion technique
-
water-system optimization technique
-
wet etching technique
-
wet etch technique
-
wire-line technique
-
zone-melting technique -
15 forge
I 1. noun1) (workshop) Schmiede, die2. transitive verb1) schmieden ( into zu)2) (fig.) schmieden [Plan, Verbindung]; schließen [Vereinbarung, Freundschaft]3) (counterfeit) fälschenII intransitive verbforge ahead — [das Tempo] beschleunigen; [Wettläufer:] vorstoßen; (fig.) vorankommen; Fortschritte machen
* * *I 1. [fo:‹] noun(a very hot oven in which metals are melted etc; a furnace: Steel is manufactured in a forge.) die Schmiede, die Esse2. verb(to shape metal by heating and hammering: He forged a horse-shoe out of an iron bar.) schmiedenII [fo:‹] verb(to copy (eg a letter or a signature) and pretend that it is genuine, usually for illegal purposes: He forged my signature.) fälschen- academic.ru/28900/forgery">forgeryIII [fo:‹] verb(to move steadily: they forged ahead with their plans.) vorwärts drängen* * *[fɔ:ʤ, AM fɔ:rʤ]I. nII. vt▪ to \forge sth1. (copy) etw fälschen2. (heat and shape) etw schmiedento \forge iron/metal Eisen/Metall schmiedena new Britain \forged in the white heat of the technological revolution ein neues Großbritannien, das in der Glut der technologischen Revolution entstandto \forge a bond/link eine Verbindung schaffento \forge a career eine Karriere schmiedenIII. vi▪ to \forge somewhere irgendwohin rasento \forge into the lead die Führung übernehmen* * *[fɔːdZ]1. n(= workshop) Schmiede f; (= furnace) Esse f2. vtto forge economic/close links with sb/sth — Wirtschaftsbeziehungen/eine enge Bindung zu jdm/etw aufbauen
2) (= counterfeit) signature, banknote fälschen3. vito forge ahead (with sth) — (mit etw) vorwärtskommen or Fortschritte machen
to forge ahead (in career) — seinen Weg machen; (Sport) vorstoßen
he forged ahead of the rest of the field — er setzte sich weit vom Rest des Feldes
* * *forge1 [fɔː(r)dʒ; US auch fəʊrdʒ]A s1. Schmiede f2. TECH Esse f, Schmiedefeuer n3. TECH Glühofen m4. TECH Hammerwerk n, Puddelhütte f:forge iron Schmiedeeisen n;B v/t1. schmieden2. formen, schaffen3. erdichten, erfinden, sich etwas ausdenken4. ein Dokument, eine Unterschrift etc fälschenC v/i schmiedenforge2 [fɔː(r)dʒ; US auch fəʊrdʒ] v/iforge through the underwood sich einen Weg durchs Unterholz bahnen* * *I 1. noun1) (workshop) Schmiede, die2. transitive verb1) schmieden ( into zu)2) (fig.) schmieden [Plan, Verbindung]; schließen [Vereinbarung, Freundschaft]3) (counterfeit) fälschenII intransitive verbforge ahead — [das Tempo] beschleunigen; [Wettläufer:] vorstoßen; (fig.) vorankommen; Fortschritte machen
* * *n.Schmiede -n f. v.erfinden v.formen v.fälschen v.schmieden v.sich Bahn brechen ausdr. -
16 Riley, James
SUBJECT AREA: Metallurgy[br]b. 1840 Halifax, Englandd. 15 July 1910 Harrogate, England[br]English steelmaker who promoted the manufacture of low-carbon bulk steel by the open-hearth process for tin plate and shipbuilding; pioneer of nickel steels.[br]After working as a millwright in Halifax, Riley found employment at the Ormesby Ironworks in Middlesbrough until, in 1869, he became manager of the Askam Ironworks in Cumberland. Three years later, in 1872, he was appointed Blast-furnace Manager at the pioneering Siemens Steel Company's works at Landore, near Swansea in South Wales. Using Spanish ore, he produced the manganese-rich iron (spiegeleisen) required as an additive to make satisfactory steel. Riley was promoted in 1874 to be General Manager at Landore, and he worked with William Siemens to develop the use of the latter's regenerative furnace for the production of open-hearth steel. He persuaded Welsh makers of tin plate to use sheets rolled from lowcarbon (mild) steel instead of from charcoal iron and, partly by publishing some test results, he was instrumental in influencing the Admiralty to build two naval vessels of mild steel, the Mercury and the Iris.In 1878 Riley moved north on his appointment as General Manager of the Steel Company of Scotland, a firm closely associated with Charles Tennant that was formed in 1872 to make steel by the Siemens process. Already by 1878, fourteen Siemens melting furnaces had been erected, and in that year 42,000 long tons of ingots were produced at the company's Hallside (Newton) Works, situated 8 km (5 miles) south-east of Glasgow. Under Riley's leadership, steelmaking in open-hearth furnaces was initiated at a second plant situated at Blochairn. Plates and sections for all aspects of shipbuilding, including boilers, formed the main products; the company also supplied the greater part of the steel for the Forth (Railway) Bridge. Riley was associated with technical modifications which improved the performance of steelmaking furnaces using Siemens's principles. He built a gasfired cupola for melting pig-iron, and constructed the first British "universal" plate mill using three-high rolls (Lauth mill).At the request of French interests, Riley investigated the properties of steels containing various proportions of nickel; the report that he read before the Iron and Steel Institute in 1889 successfully brought to the notice of potential users the greatly enhanced strength that nickel could impart and its ability to yield alloys possessing substantially lower corrodibility.The Steel Company of Scotland paid dividends in the years to 1890, but then came a lean period. In 1895, at the age of 54, Riley moved once more to another employer, becoming General Manager of the Glasgow Iron and Steel Company, which had just laid out a new steelmaking plant at Wishaw, 25 km (15 miles) south-east of Glasgow, where it already had blast furnaces. Still the technical innovator, in 1900 Riley presented an account of his experiences in introducing molten blast-furnace metal as feed for the open-hearth steel furnaces. In the early 1890s it was largely through Riley's efforts that a West of Scotland Board of Conciliation and Arbitration for the Manufactured Steel Trade came into being; he was its first Chairman and then its President.In 1899 James Riley resigned from his Scottish employment to move back to his native Yorkshire, where he became his own master by acquiring the small Richmond Ironworks situated at Stockton-on-Tees. Although Riley's 1900 account to the Iron and Steel Institute was the last of the many of which he was author, he continued to contribute to the discussion of papers written by others.[br]Principal Honours and DistinctionsPresident, West of Scotland Iron and Steel Institute 1893–5. Vice-President, Iron and Steel Institute, 1893–1910. Iron and Steel Institute (London) Bessemer Gold Medal 1887.Bibliography1876, "On steel for shipbuilding as supplied to the Royal Navy", Transactions of the Institute of Naval Architects 17:135–55.1884, "On recent improvements in the method of manufacture of open-hearth steel", Journal of the Iron and Steel Institute 2:43–52 plus plates 27–31.1887, "Some investigations as to the effects of different methods of treatment of mild steel in the manufacture of plates", Journal of the Iron and Steel Institute 1:121–30 (plus sheets II and III and plates XI and XII).27 February 1888, "Improvements in basichearth steel making furnaces", British patent no. 2,896.27 February 1888, "Improvements in regenerative furnaces for steel-making and analogous operations", British patent no. 2,899.1889, "Alloys of nickel and steel", Journal of the Iron and Steel Institute 1:45–55.Further ReadingA.Slaven, 1986, "James Riley", in Dictionary of Scottish Business Biography 1860–1960, Volume 1: The Staple Industries (ed. A.Slaven and S. Checkland), Aberdeen: Aberdeen University Press, 136–8."Men you know", The Bailie (Glasgow) 23 January 1884, series no. 588 (a brief biography, with portrait).J.C.Carr and W.Taplin, 1962, History of the British Steel Industry, Harvard University Press (contains an excellent summary of salient events).JKA -
17 installation
2) оборудование; аппаратура3) размещение, расположение4) установка ( оборудования); монтаж5) ввод в эксплуатацию; внедрение•-
absorption installation
-
acceleration installation
-
air conditioning installation
-
atomic installation
-
automatic block installation
-
blower installation
-
blow-through carburetor installation
-
boiler installation
-
cable installation
-
CAD/CAM installation
-
car installation
-
cathodic protection installation
-
charcoal installation
-
coke-discharging installation
-
coke-oven installation
-
computer installation
-
control installation
-
converter installation
-
cooling installation
-
cutting installation
-
desalination installation
-
diesel-electric propulsion installation
-
diver-assisted installation
-
diver-assist installation
-
diverless installation
-
DNC installation
-
domestic electrical installation
-
drier installation
-
dry coke-quenching installation
-
dry powder fire extinguishing installation
-
drying installation
-
dust-arrester installation
-
EB casting installation
-
EBM installation
-
effluent filter installation
-
electric installation
-
electric power installation
-
electrical propulsion installation
-
electric propulsion installation
-
electrochemical machining installation
-
electron-beam casting installation
-
electron-beam melting installation
-
electronic control fabric takedown installation
-
electronic installation
-
electronic patterning installation
-
electroslag installation
-
engine installation
-
extinguishing installation
-
factory installation
-
field installation
-
finger tight installation
-
FMS related installation
-
foam fire extinguishing installation
-
gas-cleaning installation
-
generator-transformer installation
-
heating installation
-
heat installation
-
homogenization installation
-
horizontal installation
-
hydraulic multipurpose installation
-
hydroelectric installation
-
incineration installation
-
indoor electrical installation
-
industrial electrical installation
-
influent filter installation
-
interlocking installation
-
internal installation
-
inverter installation
-
leaching installation
-
lighting installation
-
low-voltage installation
-
magnetic stirrer installation
-
multihead installation
-
multimachine installation
-
NC installation
-
offset installation
-
outdoor electrical installation
-
pipe installation
-
pouring ladle drying installation
-
power installation
-
process installation
-
propulsion installation
-
pumped-storage installation
-
pumping installation
-
racking installation
-
radio installation
-
recovery installation
-
rectifying installation
-
retrofit installation
-
robot/conveyor installation
-
robotic installation
-
route installation
-
sandblasting installation
-
sandblast installation
-
showering installation
-
software installation
-
steel-degassing installation
-
suck-through carburetor installation
-
takedown installation
-
total-energy installation
-
turbine installation
-
turbo-electric propulsion installation
-
turnout installation
-
vacuum-treating installation
-
ventilation installation
-
vertical installation
-
water-accumulator installation
-
waterfront installation -
18 Fibreglas
Fibreglas textile fibres are produced by two methods, the continuous filament process and staple fibre process. In each process glass marbles, made from melted and refined raw materials are remelted in small electrical furnaces, each of which has many small holes in the base of the melting chamber, through which the molten glass flows in fine streams by gravity. In the continuous filament process more than 100 filaments are drawn simultaneously and gathered into a thread or strand. The strand is attached to a high-speed winder that, as it draws the strand, attentuates each stream of molten glass to a fraction of the diameter of the hole through which it emerges. In the staple fibre process the streams of molten glass are struck by jets of high-pressure air or steam which attentuate the glass into fibres varying in length from 8-in. to 15-in. These fibres are driven on to a revolving drum on which they form a web, which is gathered from the drum and wound on to a tube in the form of a sliver. Strands of either continuous filament or staple fibres are twisted and plied into yarns on standard textile machinery. Fibreglas yarns are particularly suitable where fire-proofness, resistance to acids or other chemicals other than alkalis is demanded. Uses include electrical yarns, cords, tapes, cloths and sleevings which form the basis for a plain and varnished or impregnated electrical insulation material; chemical filter fabrics, anode bags used in electroplating, wicking for oil lamps and stoves, pump diaphragms, special fabrics for resisting high-temperature fumes and acids, facing materials for insulating or acoustical blankets, also rubber-coated, acid-proof and waterproof fabrics. Decorative uses include draperies, shower curtains, tablecloths, bedspreads, lamp shades and some apparel accessories, such as men's neckties. Also decorative work in architecture, dress fabrics, particularly for fancy effects, non-stretching cord for use in radio indicating dials, bookbinding, fire-screens, etc. -
19 Huntsman, Benjamin
SUBJECT AREA: Metallurgy[br]b. 1704 Barton-on-Humber, Lincolnshire, Englandd. 21 June 1776 Sheffield, England[br]English inventor of crucible steelmaking.[br]Of Dutch descent, Hunstman was apprenticed to a clockmaker at Epworth, Lincolnshire. In 1725 he set up in Doncaster as a maker of clocks, locks and roasting jacks. He made improvements in his tools but found himself hampered by the poor quality of the steel available, then made by the cementation process, which yielded a steel with a non-uniform carbon content. Around 1740, Huntsman moved to Handsworth, now part of Sheffield, and began experimenting by heating varying compositions of fuel and flux with crude steel in a crucible, to obtain a steel of uniform composition. During the years 1745 to 1750 he attained his object, but not without many unsuccessful "heats", as excavations of the site of his works now reveal. Although his steel was far better than that previously available, however, the conservative cutlers of Sheffield rejected it, claiming it was too hard to work; therefore Huntsman exported his product to France, where the cutlers promptly worked it into high-quality knives and razors that were exported to England. The Sheffield cutlers' attempts to prevent Huntsman from exporting his steel proved unsuccessful. Huntsman did not patent his process, preferring to retain his advantage by shrouding his work in secrecy, carrying out his melting at night to escape observation, but a rival cutler, Samuel Walker, gained admittance to Huntsman's works disguised as a tramp seeking food. As a result, Walker was able to make crucible steel at a handsome profit. Huntsman fought back and earned success through the sheer quality of his steel, and had to move to.a larger site at Attercliffe in 1770. Crucible steelmaking remained important through the nineteenth century although, as it was a small-scale process, its application was restricted to engineers' cutting tools and the cutting edges of certain tools.[br]Further ReadingE.W.Hulme, 1945, "The pedigree and career of Benjamin Huntsman, inventor in Europe of crucible steel", Transactions of the Newcomen Society 24:37–48.W.K.V.Gale, 1969, Iron and Steel, London: Longman.LRD -
20 electric arc phenomenon
явление электрической дуги
-
[Интент]Параллельные тексты EN-RU
Electric arc phenomenon
The electric arc is a phenomenon which takes place as a consequence of a discharge which occurs when the voltage between two points exceeds the insulating strength limit of the interposed gas; then, in the presence of suitable conditions, a plasma is generated which carries the electric current till the opening of the protective device on the supply side.
Gases, which are good insulating means under normal conditions, may become current conductors in consequence of a change in their chemical-physical properties due to a temperature rise or to other external factors.
To understand how an electrical arc originates, reference can be made to what happens when a circuit opens or closes.
During the opening phase of an electric circuit the contacts of the protective device start to separate thus offering to the current a gradually decreasing section; therefore the current meets growing resistance with a consequent rise in the temperature.
As soon as the contacts start to separate, the voltage applied to the circuit exceeds the dielectric strength of the air, causing its perforation through a discharge.
The high temperature causes the ionization of the surrounding air which keeps the current circulating in the form of electrical arc. Besides thermal ionization, there is also an electron emission from the cathode due to the thermionic effect; the ions formed in the gas due to the very high temperature are accelerated by the electric field, strike the cathode, release energy in the collision thus causing a localized heating which generates electron emission.
The electrical arc lasts till the voltage at its ends supplies the energy sufficient to compensate for the quantity of heat dissipated and to maintain the suitable conditions of temperature. If the arc is elongated and cooled, the conditions necessary for its maintenance lack and it extinguishes.
Analogously, an arc can originate also as a consequence of a short-circuit between phases. A short-circuit is a low impedance connection between two conductors at different voltages.
The conducting element which constitutes the low impedance connection (e.g. a metallic tool forgotten on the busbars inside the enclosure, a wrong wiring or a body of an animal entered inside the enclosure), subject to the difference of potential is passed through by a current of generally high value, depending on the characteristics of the circuit.
The flow of the high fault current causes the overheating of the cables or of the circuit busbars, up to the melting of the conductors of lower section; as soon as the conductor melts, analogous conditions to those present during the circuit opening arise. At that point an arc starts which lasts either till the protective devices intervene or till the conditions necessary for its stability subsist.
The electric arc is characterized by an intense ionization of the gaseous means, by reduced drops of the anodic and cathodic voltage (10 V and 40 V respectively), by high or very high current density in the middle of the column (of the order of 102-103 up to 107 A/cm2), by very high temperatures (thousands of °C) always in the middle of the current column and – in low voltage - by a distance between the ends variable from some microns to some centimeters.
[ABB]Явление электрической дуги
Электрическая дуга между двумя электродами в газе представляет собой физическое явление, возникающее в тот момент, когда напряжения между двумя электродами превышает значение электрической прочности изоляции данного газа.
При наличии подходящих условий образуется плазма, по которой протекает электрический ток. Ток будет протекать до тех пор, пока на стороне электропитания не сработает защитное устройство.
Газы, являющиеся хорошим изолятором, при нормальных условиях, могут стать проводником в результате изменения их физико-химических свойств, которые могут произойти вследствие увеличения температуры или в результате воздействия каких-либо иных внешних факторов.
Для того чтобы понять механизм возникновения электрической дуги, следует рассмотреть, что происходит при размыкании или замыкании электрической цепи.
При размыкании электрической цепи контакты защитного устройства начинают расходиться, в результате чего постепенно уменьшается сечение контактной поверхности, через которую протекает ток.
Сопротивление электрической цепи возрастает, что приводит к увеличению температуры.
Как только контакты начнут отходить один от другого, приложенное напряжение превысит электрическую прочность воздуха, что вызовет электрический пробой.
Высокая температура приведет к ионизации воздуха, которая обеспечит протекание электрического тока по проводнику, представляющему собой электрическую дугу. Кроме термической ионизации молекул воздуха происходит также эмиссия электронов с катода, вызванная термоэлектронным эффектом. Образующиеся под воздействием очень высокой температуры ионы ускоряются в электрическом поле и бомбардируют катод. Высвобождающаяся, в результате столкновения энергия, вызывает локальный нагрев, который, в свою очередь, приводит к эмиссии электронов.
Электрическая дуга длится до тех пор, пока напряжение на ее концах обеспечивает поступление энергии, достаточной для компенсации выделяющегося тепла и для сохранения условий поддержания высокой температуры. Если дуга вытягивается и охлаждается, то условия, необходимые для ее поддержания, исчезают и дуга гаснет.
Аналогичным образом возникает дуга в результате короткого замыкания электрической цепи. Короткое замыкание представляет собой низкоомное соединение двух проводников, находящихся под разными потенциалами.
Проводящий элемент с малым сопротивлением, например, металлический инструмент, забытый на шинах внутри комплектного устройства, ошибка в электромонтаже или тело животного, случайно попавшего в комплектное устройство, может соединить элементы, находящиеся под разными потенциалами, в результате чего через низкоомное соединение потечет электрический ток, значение которого определяется параметрами образовавшейся короткозамкнутой цепи.
Протекание большого тока короткого замыкания вызывает перегрев кабелей или шин, который может привести к расплавлению проводников с меньшим сечением. Как только проводник расплавится, возникает ситуация, аналогичная размыканию электрической цепи. Т. е. в момент размыкания возникает дуга, которая длится либо до срабатывания защитного устройства, либо до тех пор, пока существуют условия, обеспечивающие её стабильность.
Электрическая дуга характеризуется интенсивной ионизацией газов, что приводит к падению анодного и катодного напряжений (на 10 и 40 В соответственно), высокой или очень высокой плотностью тока в середине плазменного шнура (от 102-103 до 107 А/см2), очень высокой температурой (сотни градусов Цельсия) всегда в середине плазменного шнура и низкому падению напряжения при расстоянии между концами дуги от нескольких микрон до нескольких сантиметров.
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Англо-русский словарь нормативно-технической терминологии > electric arc phenomenon
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