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1 active furnace area
активная площадь пода печи
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[А.С.Гольдберг. Англо-русский энергетический словарь. 2006 г.]Тематики
EN
Англо-русский словарь нормативно-технической терминологии > active furnace area
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2 area
1) площадь; пространство3) поверхность4) (производственный) участок; помещение; площадка5) рабочая ячейка ( склада)•equal in area — равновеликий;area of base — площадь основания, площадь подошвы фундаментаarea of bearing — 1. площадь опоры 2. строит. площадка опиранияarea of contact — площадь поверхности контактаarea of diagram — площадь эпюры; площадь графикаarea of fracture — 1. поверхность излома 2. площадь поперечного сечения в месте разрушенияarea of occurrence — возд. район происшествияarea of water section — гидр. площадь живого сечения потокаarea of well influence — зона влияния колодца или скважины-
absorption area
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active area
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actual contact area
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actuating area
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actuation probability area
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addressable area
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adjustment control area
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advisory area
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air intake hazard area
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aircraft parking area
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airflow separation area
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airport construction area
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airport prohibited area
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airport service area
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air-route area
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alighting area
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alloy storage area
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annulus area
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antenna effective area
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antenna area
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antinode area
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aperture area
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approach area
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ash-disposal area
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auditory area
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backwater area
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bare area
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base area
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bearing surface area
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binding area
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blade area
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blade-exit area
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blind area
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blind drainage area
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boarding area
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bolted area
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bonding area
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bond area
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bore area
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bubble-melt surface area
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buffer area
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building area
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built-up area
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burning area
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catalyst surface area
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catchment area
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caved area
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central equipment area
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centralized telecine area
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centralized traffic area
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centralized video tape area
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charge-makeup area
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charging area
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chip area
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choke-tube area
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circling approach area
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clean processing area
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clearance area
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climb-out area
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clinch area
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coal area
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coherence area
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cold area
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commanded area
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common area
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compression area
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concrete area
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cone effect area
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congested area
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connector area
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conservation area
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constant area
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contact area
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contact spot area
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contaminated area
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contamination control area
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contiguous area
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contour area of contact
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control area
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controlled access area
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cooling area
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corrosion area
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coverage area
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crimp area
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critical area
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cross-sectional area
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cross-section area
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cutting area
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cylinder annular area
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dangerous area
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data-rich area
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data-sparse area
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data-void area
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decontamination area
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demixing area
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design wing area
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developed area
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developed blade area
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development area
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die attach area
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diked area
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direct transit area
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discharge area
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display area
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disposal area
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dot area
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downstream area
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drainage area
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drainless area
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dry area
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dynamic area
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echoing area
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echo area
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effective area
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effective braking area
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effective cross-sectional area
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effective cross-section area
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effective screening area
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effects area
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electrical contact area
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electroded area
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elemental area
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enclosed working area
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end safety area
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engineering area
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environmentally fragile area
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exchange area
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exclusion area
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exhaust area
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expanded blade area
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expanded area
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exposure area
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face area
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fan blast area
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felling area
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fenced-off area
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fetch area
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fill area
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film-editing area
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filter effective area
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filter open area
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filtering area
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finished-products storage area
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fixed area
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flame area
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flooded area
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flood-free area
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flooding area
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floor area
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flow area
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focus area
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forbidden area
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free-surface area
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fringe area
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functional area
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furnace area
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fusing area
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fusion area
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gases shear area
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gasket surface area
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gassy area
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gathering area
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gob area
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graticule area
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gray-scale picture area
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gross cross-sectional area
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gross cross-section area
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gross irrigable area
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ground contact area
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gutter area
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hard-core area
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hard-to-reach area
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hearth area
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heat dissipation area
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heat-affected area
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heating area
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heat-transfer area
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high-activity area
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high-beat area
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high-radiation area
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holding area
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hot area
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housing area
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illuminated area
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image area
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impact area
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impression area
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inactive area
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ingot-stripping area
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input area
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instantaneous area of flame front
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instruction area
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intended landing area
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interfacial area
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interference area
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interlocking area
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inundated area
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junction area
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knuckle area
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land area
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landing area
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lateral area
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lift irrigation area
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lift-off area
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link overlapped area
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living area
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living floor area
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load-and-unload area
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load-carrying area
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loading area
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loadout area
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localized areas of wear
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low-radiation area
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makeup area
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maneuvering area
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man-impacted area
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manned area
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manual setting-up area
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melting area
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mesa area
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metropolitan area
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mining area
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mirror area
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mold conditioning area
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mold opening area
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moment area
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movement area
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mush area
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natural area
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net cross-sectional area
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net cross-section area
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neutron migration area
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nominal contact area
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noncontact area
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nonimage area
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nonmoving area
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nonoccupied area
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nonprinting area
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nonstorage area
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nonutilizable area
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normally occupied area
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nose area
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nuclear area
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numbering area
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obstructed landing area
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open area
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open flow area
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outgassed area
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output area
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overrun safety area
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pallet area
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patch area
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pattern area
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payable area
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percent shear area
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personnel and utility area
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phosphor area
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photolithographic area
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picture area
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poor-reception area
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port area
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presentation area
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pressing area
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prewarming area
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primary area
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primary service area
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printing area
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production area
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production control area
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programmed operating area
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prohibited area
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projectedblade area
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projected area
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propeller disk area
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protected area
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quality-control area
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quality area
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quench area
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quiet area
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radar area
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radiation-control area
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real area of contact
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recording area
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record area
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refining area
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regeneration area
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reinforcing steel area
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rerecording area
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reservoir surface area
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reservoir area
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residential area
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resident area
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residential floor area
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restricted area
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retarder area
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rig deck area
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risk area
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robot area
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roof contact area
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rubbing path area
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rudder area
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run-up area
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rural area
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safe operating area
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safety area
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sail area
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save area
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scanned area
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scrap-consuming area
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scrap-disposal area
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scrap-grading area
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scratch area
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screen area
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sealing area
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seal area
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search area
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secondary area
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sectional area
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section area
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seeking area
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segregated area
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service area
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serviceable area
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setting-up area
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shaded area
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shadow area
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shareable area
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shoe pad transition area
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shooting area
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sintering area
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site area
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skip area
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slag-line area
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slot area
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slowing-down area of neutron
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snow-covered area
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solid area
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sound area
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sound-track area
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special work permit area
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specific floor area
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specific surface area
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spliced area
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spoil area
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stack area
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stockline area
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stool conditioning area
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storage area
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stripped area
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subsidence area
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superheated area
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surface area
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switching area
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takeoff area
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takeoff flight path area
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tape area
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taphole area
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target area
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technical-equipment area
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technical area
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telecine area
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tension area
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terminal area
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terminal control area
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test area
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throat area
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tongs area of pipe
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tool service area
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tool-presetting area
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total area
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total irrigation area
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total tuyere area
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transient area
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turnaround area
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tuyere area
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type area
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unattacked area
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undershoot area
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ungaged area
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uniform area
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unobstructed landing area
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upstream area
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urban area
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usable area
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user area
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valve fillet area
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valve seating face area
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video tape recording area
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video tape area
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viewing area
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vision control area
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vulnerable area
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waste area
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waste-metal area
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waste-storage area
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water catchment area
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waterplane area
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water-surface area
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wear track area
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weld metal area
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well drainage area
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wellhead area
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wetted area
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wildlife area
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window area
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worked-out area
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working area
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yard area
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yoke area -
3 активная площадь пода печи
активная площадь пода печи
—
[А.С.Гольдберг. Англо-русский энергетический словарь. 2006 г.]Тематики
EN
Русско-английский словарь нормативно-технической терминологии > активная площадь пода печи
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4 grate
1) решетка2) колосниковая решетка; -
5 Fox, Samson
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering, Metallurgy, Steam and internal combustion engines[br]b. 11 July 1838 Bowling, near Bradford, Yorkshire, Englandd. 24 October 1903 Walsall, Staffordshire, England[br]English engineer who invented the corrugated boiler furnace.[br]He was the son of a cloth mill worker in Leeds and at the age of 10 he joined his father at the mill. Showing a mechanical inclination, he was apprenticed to a firm of machine-tool makers, Smith, Beacock and Tannett. There he rose to become Foreman and Traveller, and designed and patented tools for cutting bevelled gears. With his brother and one Refitt, he set up the Silver Cross engineering works for making special machine tools. In 1874 he founded the Leeds Forge Company, acting as Managing Director until 1896 and then as Chairman until shortly before his death.It was in 1877 that he patented his most important invention, the corrugated furnace for steam-boilers. These furnaces could withstand much higher pressures than the conventional form, and higher working pressures in marine boilers enabled triple-expansion engines to be installed, greatly improving the performance of steamships, and the outcome was the great ocean-going liners of the twentieth century. The first vessel to be equipped with the corrugated furnace was the Pretoria of 1878. At first the furnaces were made by hammering iron plates using swage blocks under a steam hammer. A plant for rolling corrugated plates was set up at Essen in Germany, and Fox installed a similar mill at his works in Leeds in 1882.In 1886 Fox installed a Siemens steelmaking plant and he was notable in the movement for replacing wrought iron with steel. He took out several patents for making pressed-steel underframes for railway wagons. The business prospered and Fox opened a works near Chicago in the USA, where in addition to wagon underframes he manufactured the first American pressed-steel carriages. He later added a works at Pittsburgh.Fox was the first in England to use water gas for his metallurgical operations and for lighting, with a saving in cost as it was cheaper than coal gas. He was also a pioneer in the acetylene industry, producing in 1894 the first calcium carbide, from which the gas is made.Fox took an active part in public life in and around Leeds, being thrice elected Mayor of Harrogate. As a music lover, he was a benefactor of musicians, contributing no less than £45,000 towards the cost of building the Royal College of Music in London, opened in 1894. In 1897 he sued for libel the author Jerome K.Jerome and the publishers of the Today magazine for accusing him of misusing his great generosity to the College to give a misleading impression of his commercial methods and prosperity. He won the case but was not awarded costs.[br]Principal Honours and DistinctionsRoyal Society of Arts James Watt Silver Medal and Howard Gold Medal. Légion d'honneur 1889.Bibliography1877, British Patent nos. 1097 and 2530 (the corrugated furnace or "flue", as it was often called).Further ReadingObituary, 1903, Proceedings of the Institution of Mechanical Engineers: 919–21.Obituary, 1903, Proceedings of the Institution of Civil Engineers (the fullest of the many obituary notices).G.A.Newby, 1993, "Behind the fire doors: Fox's corrugated furnace 1877 and the high pressure steamship", Transactions of the Newcomen Society 64.LRD -
6 Hall, Joseph
SUBJECT AREA: Metallurgy[br]b. 1789d. 1862[br]English ironmaker who invented the wet puddling process.[br]Hall was a practical man with no theoretical background: his active years were spent at Bloomfield Ironworks, Tipton, Staffordshire. Around 1816 he began experimenting in the production of wrought iron. At that time, blast-furnace or cast iron was converted to wrought iron by the dry puddling process invented by Henry Cort in 1784. In this process, the iron was decarburized (i.e. had its carbon removed) by heating it in a current of air in a furnace with a sand bed. Some of the iron combined with the silica in the sand to form a slag, however, so that no less than 2 tons of cast iron were needed to produce 1 ton of wrought. Hall found that if bosh cinder was charged into the furnace, a vigorous reaction occurred in which the cast iron was converted much more quickly than before, to produce better quality wrought iron, a ton of which could be formed by no more than 21 cwt (1,067 kg) of cast iron. Because of the boiling action, the process came to be known as pig boiling. Bosh cinder, essentially iron oxide, was formed in the water troughs or boshes in which workers cooled their tools used in puddling and reacted with the carbon in the cast iron. The advantages of pig boiling over dry puddling were striking enough for the process to be widely used by the late 1820s. By mid-century it was virtually the only process used for producing wrought iron, an essential material for mechanical and civil engineering during the Industrial Revolution. Hall reckoned that if he had patented his invention he would have "made a million". As luck would have it, the process that he did patent in 1838 left his finances unchanged: this was for the roasting of cinder for use as the base of the puddling furnace, providing better protection than the bosh cinder for the iron plates that formed the base.[br]Bibliography1857, The Iron Question Considered in Connection with Theory, Practice and Experience with Special Reference to the Bessemer Process, London.Further ReadingJ.Percy, 1864, Metallurgy. Iron and Steel, London, pp. 670 ff. W.K.V.Gale, Iron and Steel, London: Longmans, pp. 46–50.LRD -
7 Cowper, Edward Alfred
SUBJECT AREA: Metallurgy[br]b. 10 December 1819 London, Englandd. 9 May 1893 Weybridge, Surrey, England[br]English inventor of the hot-blast stove used in ironmaking.[br]Cowper was apprenticed in 1834 to John Braithwaite of London and in 1846 obtained employment at the engineers Fox \& Henderson in Birmingham. In 1851 he was engaged in the contract drawings for the Crystal Palace housing the Great Exhibition, and in the same year he set up in London as a consulting engineer. Cowper designed the 211 ft (64.3 m) span roof of Birmingham railway station, the first large-span station roof to be constructed. Cowper had an inventive turn of mind. While still an apprentice, he devised the well-known railway fog-signal and, at Fox \& Henderson, he invented an improved method of casting railway chairs. Other inventions included a compound steam-engine with receiver, patented in 1857; a bicycle wheel with steel spokes and rubber tyre (1868); and an electric writing telegraph (1879). Cowper's most important invention by far was the hot-blast stove, the first application of C.W. Siemens's regenerative principle to ironmaking, patented in 1857. Waste gases from the blast furnace were burnt in an iron chamber lined with a honeycomb of firebricks. When they were hot, the gas was directed to a second similar chamber while the incoming air blast for the blast furnace was heated by passing it through the first chamber. The stoves alternatively received and gave up heat and the heated blast, introduced by J.B. Neilson, led to considerable fuel economies in blast-furnace operation; the system is still in use. Cowper played an active part in the engineering institutions of his time, becoming President of the Institution of Mechanical Engineers in 1880–1. He was commissioned by the Science and Art Department to catalogue the collections of machinery and inventions at the South Kensington Museum, whose science collections now form the Science Museum, London.[br]Principal Honours and DistinctionsPresident, Institution of Mechanical Engineers 1880–1.Further ReadingObituary, 1893, Journal of the Iron and Steel Institute: 172–3, London.W.K.V.Gale, 1969, Iron and Steel, London: Longmans, pp. 42, 75 (describes his hot-blast stoves).LRD -
8 Coster, John
[br]b. c. 1647 Gloucestershire, Englandd. 13 October 1718 Bristol, England[br]English innovator in the mining, smelting and working of copper.[br]John Coster, son of an iron-forge manager in the Forest of Dean, by the age of 38 was at Bristol, where he was "chief agent and sharer therein" in the new lead-smelting methods using coal fuel. In 1685 the work, under Sir Clement Clerke, was abandoned because of patent rights claimed by Lord Grandison, who financed of earlier attempts. Clerke's business turned to the coal-fired smelting of copper under Coster, later acknowledged as responsible for the subsequent success through using an improved reverberatory furnace which separated coal fume from the ores being smelted. The new technique, applicable also to lead and tin smelting, revitalized copper production and provided a basis for new British industry in both copper and brass manufacture during the following century. Coster went on to manage a copper-smelting works, and by the 1690s was supplying Esher copper-and brass-works in Surrey from his Redbrook, Gloucestershire, works on the River Wye. In the next decade he extended his activities to Cornish copper mining, buying ore and organizing ore sales, and supplying the four major copper and brass companies which by then had become established. He also made copper goods in additional water-powered rolling and hammer mills acquired in the Bristol area. Coster was ably assisted by three sons; of these, John and Robert were mainly active in Cornwall. In 1714 the younger John, with his father, patented an "engine for drawing water out of deep mines". The eldest son, Thomas, was more involved at Redbrook, in South Wales and the Bristol area. A few years after the death of his father, Thomas became partner in the brass company of Bristol and sold them the Redbrook site. He became Member of Parliament for Bristol and, by then the only surviving son, planned a large new smelting works at White Rock, Swansea, South Wales, before his death in 1734. Partners outside the family continued the business under a new name.[br]Bibliography1714, British patent 397, with John Coster Jr.Further ReadingRhys Jenkins, 1942, "Copper works at Redbrook and Bristol", Transactions of the Bristol and Gloucestershire Archaeological Society 63.Joan Day, 1974–6, "The Costers: copper smelters and manufacturers", Transactions of the Newcomen Society 47:47–58.JD -
9 Deere, John
SUBJECT AREA: Agricultural and food technology[br]b. 7 February 1804 Rutland, Vermont, USAd. 17 May 1886 USA[br]American inventor and manufacturer of agricultural equipment.[br]John Deere was the son of a tailor, and first worked as a tanner before becoming apprenticed to a blacksmith. He married Demarius Lamb in 1827, but it appears that competition for blacksmiths was fierce, and the Deere family moved frequently. Two attempts to establish forges ended in fires, and changing partnerships and arguments over debts were to be a feature of Deere's working life. In 1836 John Deere moved west on his own, in an attempt to establish himself. He settled in Grand Detour, Illinois. In this new frontier a blacksmith's skills were sought after, and the blacksmith, with no ready supply of raw materials, had to be able to operate both a furnace for melting metal and a forge for working it. Deere was sufficiently successful for his family to be able to join him. A chance visit to a sawmill and the acquisition of a broken saw blade led to the making of a plough that was to establish John Deere in manufacturing. There were two distinctive features associated with the plough: the soil in the area failed to stick to the steel blade, with obvious benefits to the draught of the implement; and second, the shape of the working mouldboard was square. The reputation that developed with his first three ploughs established that Deere had made the transition from blacksmith to manufacturer.Over the next decade he had a number of partnerships and eventually set up a factory in Moline, Illinois, in 1848. The following year he sold 2,136 ploughs, and by early 1850 he was producing 350 ploughs per month. Deere was devastated by the loss of his eldest son in the year that the company moved to Moline. However, his second son, Charles, joined him in 1851 and was to be a major influence on the way in which the company developed over the next half-century. The company branched out into the production of cultivators, harrows, drills and wagons. John Deere himself played an active part in the company, but also played an increasing role in public life, with a particular interest in education. The company was incorporated in 1868.[br]Further ReadingThe following both provide biographical details of John Deere, but are mainly concerned with the company and the equipment it produced: W.G.Broehl, 1984, John Deere's Company: A History of Deere and Company and itsTimes, American Society of Agricultural Engineers.D.Macmillan, 1988, John Deere Tractors and Equipment, American Society of Agricultural Engineers.AP
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