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1 wet collodion process
English-Russian big polytechnic dictionary > wet collodion process
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2 wet collodion process
Полиграфия: мокроколлодионный процесс -
3 wet collodion process
תהליך קולודיון רטוב, תהליך לוח רטוב, תהליך ישן לכנת נגטיבי לצילום שבו לוח זכוכית מצופה בקולודיון ומלח לידי נתבל בתמיסת מלח של כסף לפני הצילום* * *◙ םוליצה ינפל ףסכ לש חלמ תסימתב לבתנ ידיל חלמו ןוידולוקב הפוצמ תיכוכז חול ובש םוליצל יביטגנ תנכל ןשי ךילהת,בוטר חול ךילהת,בוטר ןוידולוק ךילהת◄ -
4 wet-collodion process
< phot> ■ Nasskollodiumverfahren n -
5 wet-collodion process
English-Spanish technical dictionary > wet-collodion process
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6 wet collodion process
n PRINT Naßkollodiumverfahren ntDictionary English-German Informatics > wet collodion process
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7 wet collodion
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8 collodion
коллодий коллодионном фотографическом процессе); мокроколлодионный -
9 wet
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10 process
1) процесс2) (технологический) процесс; (технологическая) обработка3) технологический приём; способ4) технология5) режим; ход (процесса)6) обрабатывать, подвергать обработке7) подвергать анализу, анализировать•to design process — разрабатывать технологию-
acetone-acetylene process
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acetylene process
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Acheson process
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acid Bessemer process
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acid process
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acid reclaiming process
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acyclic process
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Adapti investment casting process
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additive process
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adiabatic process
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Aero case process
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aerobic process
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age-dependent process
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air blast process
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air-sand process
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Alcan process
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Al-Dip process
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alfin process
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alkali reclaiming process
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alkaline process
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Allis-Chalmers agglomeration reduction process
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ALT process
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aluminothermic process
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anaerobic process
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anamorphotic process
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annealing-in-line process
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anode process
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anodic electrode process
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AOD process
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aqua-cast process
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ARBED-ladle-treatment process
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arc-air process
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arc-remelting process
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argon-oxygen-decarburization process
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ASEA-SKF process
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autoregressive process
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averaging process
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Azincourt process
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azo coupling process
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background process
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bag process
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BAP process
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Barrow process
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Basett process
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basic Bessemer process
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basic oxygen process
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basic process
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basic-arc process
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batch process
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biofiltration process
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bipolar process
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bipolar-FET process
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bipolar-MOS process
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BISRA degassing process
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black-heart process
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Blackodising process
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blast-furnace process
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Blaw-Knox process
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bleaching process
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Bochumer-Verein process
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boiling process
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bonding process
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bottom-argon-process process
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broadband random process
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bromoil transfer process
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bromoil process
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bubble-column process
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bubble-hearth process
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buffer-slag process
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Calmes process
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Canadizing process
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carbon mold process
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carbon process
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carbon-arc process
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carbon-in-leach process
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carbon-in-pulp process
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carbothermic process
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carbro process
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carrier-gas degassing process
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cascade process
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cast shell process
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catalytic DENO process
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cathodic process
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CC-CR process
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CC-DR process
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CC-HCR process
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cementation process
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cementation-in-pulp process
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cementing process
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centrifugal spinning process
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cermet process
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CESM process
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CEVAM process
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charge transfer process
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chemical vapor deposition process
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chemical-bonding process
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Chenot process
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china process
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cine exposure process
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cine process
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CLC process
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clean burn process
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cloudburst process
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CLU process
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CMOS process
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CNC process
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CO2 silicate process
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coal reduction process
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coal to gas process
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coal-gas-sumitomo process
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coal-oxygen-injection process
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COIN process
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cold box process
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cold doping process
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cold process
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cold scrap process
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cold type process
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collodion process
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color process
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concurrent processes
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consteel process
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consumable electrode vacuum arc melting process
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contact process
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continuous annealing process
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continuous casting-cleaning rolling process
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continuous casting-direct rolling process
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continuous casting-hot charging and rolling process
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continuous electroslag melting process
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continuous metal cast process
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continuous-on-line control process
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continuous-time process
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controlled pressure pouring process
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controlled process
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converter process
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cooking process
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coppering process
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copying process
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coupled cathodic-anodic process
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cracking process
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Creusot Loire Uddenholm process
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critical process
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cumulative process
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cuprammonium process
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curing process
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CVD process
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cyclic process
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Cyclosteel process
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Czochralski process
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daguerre photographic process
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dense-media process
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Desco process
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deterministic process
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developing process
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DH degassing process
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diabatic process
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diazo process
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diffused planar process
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diffusion process
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diffusion transfer process
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dip-forming process
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direct iron process
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direct process
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direct reduction process
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direct-sintering process
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discrete-time process
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discrete process
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DLM process
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Domnarvet process
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Dored process
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double-crucible process
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double-epi process
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doubling process
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D-process
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DR process
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drop-molding process
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dry adiabatic process
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dry process
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dry-blanch-dry process
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duplex process
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easy drawing process
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EBM process
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EBR process
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EF-AOD process
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electric furnace-argon oxygen decarburization process
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electroarc process
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electrocatalytic process
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electrocolor process
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electrodialysis reversal process
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electroflux-remelting process
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electromembrane process
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electron-beam-melting process
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electron-beam-refining process
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electrophotoadhesive process
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electrophotographic process
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electroslag refining process
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electroslag remelting process
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electroslag remelt process
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electrostatographic process
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electrostream process
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Elo-Vac process
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elquench process
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endothermic process
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energy efficient process
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entropy process
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enzymatic process
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EPIC process
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epidemic process
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epitaxial growth process
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epitaxy growth process
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ergodic process
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ESR process
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Estel process
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etching process
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exoergic process
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exothermic process
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extrusion-molded neck process
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ferroprussiate process
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Ferrox process
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filming process
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filtration-chlorination process
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Finkl-Mohr process
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FIOR process
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first process
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fixed-bed MTG process
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flash steel direct reduction process
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float process
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float-and-sink process
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float-zone process
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flow process
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fluid iron ore reduction process
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fluid-bed MTG process
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fluidized roasting process
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fluid-sand process
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FMC coke process
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foaming process
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foehn process
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food-machinery and chemical coke process
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foreground process
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Foren process
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FOS process
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freeze concentration process
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fuel-oxygen-scrap process
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full-mold process
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fusion-casting process
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Futacuchi process
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Gaussian process
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Gero mold degassing process
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Gero vacuum casting process
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GGS process
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girbitol process
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gradual reduction process
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growing process
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growth process
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gypsum-sulfuric acid process
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Hall electrolytic process
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Harris process
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hazardous process
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H-coal process
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heat-transfer process
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heavy-media process
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hibernating process
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HI-GAS process
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high-frequency induction process
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HIP process
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H-iron process
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Hoope process
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hot isostatic pressing process
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hot process
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hot-metal process
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hot-metal-and-scrap process
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hot-type process
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hydrogasification process
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hydrotype process
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HyL process
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IC-DR process
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image process
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imbibition process
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immiscible displacement process
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implantation process
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impurity doping process
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in-bulk process
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inchrome process
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in-draw process
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inductoslag-melting process
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ingot casting direct rolling process
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injection molding process
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in-line process
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Inred process
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interpolation process
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investment process
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ion-implantation process
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irreversible process
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isentropic process
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ISM process
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isobaric process
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isochoric process
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isoenthalpic process
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isoentropic process
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isometric process
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isoplanar process
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isothermal process
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iterative process
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jet-expanding process
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Kaldo process
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katadyn process
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Kawasaki-bottom-oxygen-process process
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Kawasaki-Gas-Lime-Injection process
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K-BOP process
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KEK process
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KG-LI process
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kiln-reduction process
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KIVCET cyclone smelting process
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KIVCET process
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knit-deknit process
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koetherizing process
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KR process
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kraft process
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lance bubbling equilibrium process
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LBE process
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LD-AB process
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LD-AC process
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LD-AOD process
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LD-argon bottom process
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LD-argon oxygen decarburization process
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LD-CB process
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LD-circle lance process
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LD-CL process
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LD-combination blow process
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LD-HC top and botton blowing process
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LDK process
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LD-Kawasaki-Gas process
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LD-KG process
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LD-OB process
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LD-OTB process
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LD-oxygen bottom process
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LD-oxygen-top-bottom process
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lift-off process
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liquefaction process
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liquid gas plug process
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liquid-phase process
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loop transfer process
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lost core process
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low-waste technological process
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LSI process
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LVR process
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LVS process
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Mannesmann powder process
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mapping process
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Markovian process
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Markov process
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masking process
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matte fuming process
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melting process
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mercast process
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Midland-Ross process
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Midrex process
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migration process
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miscible displacement process
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miscible plug process
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mixed autoregressive-moving average process
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moist adiabatic process
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Molynutz process
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monochrome process
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monolithic process
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MOS process
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MOSFET process
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motion-picture process
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moving average process
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narrowband random process
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Neely process
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negative-positive process
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Nitemper process
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no pickle process
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nonflow process
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non-Gaussian process
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Nord-Fuvo process
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Nu-iron process
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OBM process
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OG process
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OLP converter process
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one-way process
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open-hearth process
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orbitread process
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ore process
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Orthoflow cracking process
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Orthoforming process
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orthogonal increment process
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oxidation process
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oxide-isolated process
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oxygen-blow process
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oxygen-gas process
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oxygen-lancing process
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oxygen-steelmaking process
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packaging process
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pad-batch dyeing process
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pad-dry dyeing process
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pad-jig dyeing process
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pad-roll dyeing process
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pad-steam dyeing process
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pad-steam vat-print process
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PAMCO-hot-alloy process
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parent process
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PCR process
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Perrin process
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PHA process
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phonon process
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photoelectric process
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photomechanical process
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photovoltaic process
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pig iron-scrap process
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pig-and-ore process
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pigment padding dying process
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pigment padding process
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pigment process
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pinatype process
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planar process
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plasma etching process
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plasma etch process
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plasma process
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plasma-arc process
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Plasmamelt process
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Plasmared process
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plaster mold process
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plastic wirecut process
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polytropic process
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powder silicon ribbon process
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power-press process
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prepolymer process
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prepress processes
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pressure-driven membrane process
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primuline process
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propane-acid process
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pulsating mixing process
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Purex process
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pushbench process
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Q-BOP process
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QDT process
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quality basic oxygen process process
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quasi-independent processes
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quick and direct tapping process
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ram process
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random process
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rapid solidification plasma deposition process
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rayon continuous process
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receiving process
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reclamator reclaiming process
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recurrent process
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redox process
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reducing process
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reduction-smelting process
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relaxation process
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repetitive process
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reproduction process
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reversal process
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reversible process
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RH process
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RH-OB process
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ribbon process
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R-N direct-reduction process
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roasting-sintering process
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roast-leaching process
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robot-controlled process
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rongalit-potash process
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rotor process
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rustless process
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sample process
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schoop process
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scrap-and-pig process
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scrap-conditioning process
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scrap-ore process
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screen printed process
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self-developing process
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self-healing process
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semibatch process
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semiconductor process
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sending process
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Sendzimir coating process
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sequential process
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silicon-gate MOS process
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silicon-gate process
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silk-screen process
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single-pumpdown process
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SIP process
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skein spinning process
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Skinner multiple-hearth process
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slag minimum process
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slip-casting process
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slow down process
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SLPM process
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SL-RN metallization process
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SL-RN reduction process
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solid source diffusion process
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solution regrowth process
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solvent extraction-electrowinning process
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solvent plug process
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SOS process
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spin-draw-texturizing process
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spinylock process
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sponge iron process
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spontaneous process
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Stanal process
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stationary random process
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STB process
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steady-flow process
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steam-blow process
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steelmaking process
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Stelmor process
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step and repeat process
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stochastic process
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stuffer box process
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submerged arc process
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subtractive process
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suck-and-blow process
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Sulf BT process
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Sulfinuz process
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Sumitomo-slag all recycling process
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Sumitomo-top-bottom process
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Sursulf process
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system process
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TBM process
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T-die process
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Technamation process
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thermal DeNOx process
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Therm-i-Vac process
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Thermo-Flow process
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thermoplastic process
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Thomas process
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Thorex process
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three-color process
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Thyssen-blast-metallurgy process
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Tifran process
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tightly coupled processes
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time-varying process
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trichromatic process
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triplex process
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Tropenas converter process
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Tufftride process
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Tufftride TF1 process
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uncertain process
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user process
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vacuum arc remelting process
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vacuum casting process
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vacuum deoxidation process
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vacuum induction refining process
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vacuum stream-droplet process
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vacuum-arc degassing process
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vacuum-carbodeoxidation process
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vacuum-carbonate process
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vacuum-induction melting process
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vacuum-melting process
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vacuum-metallothermic process
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vacuum-oxygen-decarburization process
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VAD process
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VAR process
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VAW process
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VHSIC process
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vigom process
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VIR process
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viscose process
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visual process
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VLSI process
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VOD process
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waiting process
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water gas process
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waterfall process
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wet process
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white-heart process
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Zinal process
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zinc distilling process -
11 process
1) способ; технология; процесс2) обрабатывать3) воспроизводить фотомеханическим способом4) проявлятьАнгло-русский словарь по полиграфии и издательскому делу > process
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12 dry collodion
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13 Archer, Frederick Scott
SUBJECT AREA: Photography, film and optics[br]b. 1813 Bishops Stortford, Hertfordshire, Englandd. May 1857 London, England[br]English photographer, inventor of the wet-collodion process, the dominant photographic process between 1851 and c.1880.[br]Apprenticed to a silversmith in London, Archer's interest in coin design and sculpture led to his taking up photography in 1847. Archer began experiments to improve Talbot's calotype process and by 1848 he was investigating the properties of a newly discovered material, collodion, a solution of gun-cotton in ether. In 1851 Archer published details of a process using collodion on glass plates as a carrier for silver salts. The process combined the virtues of both the calotype and the daguerreotype processes, then widely practised, and soon displaced them from favour. Collodion plates were only sensitive when moist and it was therefore essential to use them immediately after they had been prepared. Popularly known as "wet plate" photography, it became the dominant photographic process for thirty years.Archer introduced other minor photographic innovations and in 1855 patented a collodion stripping film. He had not patented the wet-plate process, however, and made no financial gain from his photographic work. He died in poverty in 1857, a matter of some embarrassment to his contemporaries. A subscription fund was raised, to which the Government was subsequently persuaded to add an annual pension.[br]Bibliography1851, Chemist (March) (announced Archer's process).Further ReadingJ.Werge, 1890, The Evolution of Photography.H.Gernsheim and A.Gernsheim, 1969, The History of "Photography", rev. edn, London.JWBiographical history of technology > Archer, Frederick Scott
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14 Muybridge, Eadweard
SUBJECT AREA: Photography, film and optics[br]b. 9 April 1830 Kingston upon Thames, Englandd. 8 May 1904 Kingston upon Thames, England[br]English photographer and pioneer of sequence photography of movement.[br]He was born Edward Muggeridge, but later changed his name, taking the Saxon spelling of his first name and altering his surname, first to Muygridge and then to Muybridge. He emigrated to America in 1851, working in New York in bookbinding and selling as a commission agent for the London Printing and Publishing Company. Through contact with a New York daguerreotypist, Silas T.Selleck, he acquired an interest in photography that developed after his move to California in 1855. On a visit to England in 1860 he learned the wet-collodion process from a friend, Arthur Brown, and acquired the best photographic equipment available in London before returning to America. In 1867, under his trade pseudonym "Helios", he set out to record the scenery of the Far West with his mobile dark-room, christened "The Flying Studio".His reputation as a photographer of the first rank spread, and he was commissioned to record the survey visit of Major-General Henry W.Halleck to Alaska and also to record the territory through which the Central Pacific Railroad was being constructed. Perhaps because of this latter project, he was approached by the President of the Central Pacific, Leland Stanford, to attempt to photograph a horse trotting at speed. There was a long-standing controversy among racing men as to whether a trotting horse had all four hooves off the ground at any point; Stanford felt that it did, and hoped than an "instantaneous" photograph would settle the matter once and for all. In May 1872 Muybridge photographed the horse "Occident", but without any great success because the current wet-collodion process normally required many seconds, even in a good light, for a good result. In April 1873 he managed to produce some better negatives, in which a recognizable silhouette of the horse showed all four feet above the ground at the same time.Soon after, Muybridge left his young wife, Flora, in San Francisco to go with the army sent to put down the revolt of the Modoc Indians. While he was busy photographing the scenery and the combatants, his wife had an affair with a Major Harry Larkyns. On his return, finding his wife pregnant, he had several confrontations with Larkyns, which culminated in his shooting him dead. At his trial for murder, in February 1875, Muybridge was acquitted by the jury on the grounds of justifiable homicide; he left soon after on a long trip to South America.He again took up his photographic work when he returned to North America and Stanford asked him to take up the action-photography project once more. Using a new shutter design he had developed while on his trip south, and which would operate in as little as 1/1,000 of a second, he obtained more detailed pictures of "Occident" in July 1877. He then devised a new scheme, which Stanford sponsored at his farm at Palo Alto. A 50 ft (15 m) long shed was constructed, containing twelve cameras side by side, and a white background marked off with vertical, numbered lines was set up. Each camera was fitted with Muybridge's highspeed shutter, which was released by an electromagnetic catch. Thin threads stretched across the track were broken by the horse as it moved along, closing spring electrical contacts which released each shutter in turn. Thus, in about half a second, twelve photographs were obtained that showed all the phases of the movement.Although the pictures were still little more than silhouettes, they were very sharp, and sequences published in scientific and photographic journals throughout the world excited considerable attention. By replacing the threads with an electrical commutator device, which allowed the release of the shutters at precise intervals, Muybridge was able to take series of actions by other animals and humans. From 1880 he lectured in America and Europe, projecting his results in motion on the screen with his Zoopraxiscope projector. In August 1883 he received a grant of $40,000 from the University of Pennsylvania to carry on his work there. Using the vastly improved gelatine dry-plate process and new, improved multiple-camera apparatus, during 1884 and 1885 he produced over 100,000 photographs, of which 20,000 were reproduced in Animal Locomotion in 1887. The subjects were animals of all kinds, and human figures, mostly nude, in a wide range of activities. The quality of the photographs was extremely good, and the publication attracted considerable attention and praise.Muybridge returned to England in 1894; his last publications were Animals in Motion (1899) and The Human Figure in Motion (1901). His influence on the world of art was enormous, over-turning the conventional representations of action hitherto used by artists. His work in pioneering the use of sequence photography led to the science of chronophotography developed by Marey and others, and stimulated many inventors, notably Thomas Edison to work which led to the introduction of cinematography in the 1890s.[br]Bibliography1887, Animal Locomotion, Philadelphia.1893, Descriptive Zoopraxography, Pennsylvania. 1899, Animals in Motion, London.1901, The Human Figure in Motion, London.Further Reading1973, Eadweard Muybridge: The Stanford Years, Stanford.G.Hendricks, 1975, Muybridge: The Father of the Motion Picture, New York. R.Haas, 1976, Muybridge: Man in Motion, California.B.Coe, 1992, Muybridge and the Chromophoto-graphers, London.BC -
15 Niepce de St Victor, Claude Félix Abel
SUBJECT AREA: Photography, film and optics[br]b. 1805 Saint-Cyr, Franced. 1870 France[br]French soldier and photographic scientist, inventor of the first practicable glass negative process.[br]A cousin of the photographic pioneer J.N. Niepce, he attended the military school of Saumur, graduating in 1827. Niepce de St Victor had wide scientific interests, but came to photography indirectly from experiments he made on fading dyes in military uniforms. He was transferred to the Paris Municipal Guard in 1845 and was able to set up a chemical laboratory to conduct research. From photographic experiments performed in his spare time, Niepce de St Victor devised the first practicable photographic process on glass in 1847. Using albumen derived from the white of eggs as a carrier for silver iodide, he prepared finely detailed negatives which produced positive prints far sharper than those made with the paper negatives of Talbot's calotype process. Exposure times were rather long, however, and the albumen-negative process was soon displaced by the wet-collodion process introduced in 1851, although albumen positives on glass continued to be used for high-quality stereoscopic views and lantern slides. In 1851 Niepce de St Victor described a photographic colour process, and between 1853 and 1855 he developed his famous cousin's bitumen process into a practicable means of producing photographically derived printing plates. He then went on to investigate the use of uranium salts in photography. He presented twenty-six papers to the Académie des Sciences between 1847 and 1862.[br]Bibliography1847, Comptes Rendus 25(25 October):586 (describes his albumen-on-glass process).Further ReadingJ.M.Eder, 1945, History of Photography, trans. E.Epstean, New York (provides details of his contributions to photography).JWBiographical history of technology > Niepce de St Victor, Claude Félix Abel
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16 мокроколлодионный процесс
Polygraphy: wet collodion process, wet processУниверсальный русско-английский словарь > мокроколлодионный процесс
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17 Nasskollodiumverfahren
n < phot> ■ wet-collodion process; wet-plate processGerman-english technical dictionary > Nasskollodiumverfahren
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18 Sutton, Thomas
SUBJECT AREA: Photography, film and optics[br]b. 1819 Englandd. 1875 Jersey, Channel Islands[br]English photographer and writer on photography.[br]In 1841, while studying at Cambridge, Sutton became interested in photography and tried out the current processes, daguerreotype, calotype and cyanotype among them. He subsequently settled in Jersey, where he continued his photographic studies. In 1855 he opened a photographic printing works in Jersey, in partnership with L.-D. Blanquart- Evrard, exploiting the latter's process for producing developed positive prints. He started and edited one of the first photographic periodicals, Photographic Notes, in 1856; until its cessation in 1867, his journal presented a fresher view of the world of photography than that given by its London-based rivals. He also drew up the first dictionary of photography in 1858.In 1859 Sutton designed and patented a wideangle lens in which the space between two meniscus lenses, forming parts of a sphere and sealed in a metal rim, was filled with water; the lens so formed could cover an angle of up to 120 degrees at an aperture of f12. Sutton's design was inspired by observing the images produced by the water-filled sphere of a "snowstorm" souvenir brought home from Paris! Sutton commissioned the London camera-maker Frederick Cox to make the Panoramic camera, demonstrating the first model in January 1860; it took panoramic pictures on curved glass plates 152×381 mm in size. Cox later advertised other models in a total of four sizes. In January 1861 Sutton handed over manufacture to Andrew Ross's son Thomas Ross, who produced much-improved lenses and also cameras in three sizes. Sutton then developed the first single-lens reflex camera design, patenting it on 20 August 1961: a pivoted mirror, placed at 45 degrees inside the camera, reflected the image from the lens onto a ground glass-screen set in the top of the camera for framing and focusing. When ready, the mirror was swung up out of the way to allow light to reach the plate at the back of the camera. The design was manufactured for a few years by Thomas Ross and J.H. Dallmeyer.In 1861 James Clerk Maxwell asked Sutton to prepare a series of photographs for use in his lecture "On the theory of three primary colours", to be presented at the Royal Institution in London on 17 May 1861. Maxwell required three photographs to be taken through red, green and blue filters, which were to be printed as lantern slides and projected in superimposition through three projectors. If his theory was correct, a colour reproduction of the original subject would be produced. Sutton used liquid filters: ammoniacal copper sulphate for blue, copper chloride for the green and iron sulphocyanide for the red. A fourth exposure was made through lemon-yellow glass, but was not used in the final demonstration. A tartan ribbon in a bow was used as the subject; the wet-collodion process in current use required six seconds for the blue exposure, about twice what would have been needed without the filter. After twelve minutes no trace of image was produced through the green filter, which had to be diluted to a pale green: a twelve-minute exposure then produced a serviceable negative. Eight minutes was enough to record an image through the red filter, although since the process was sensitive only to blue light, nothing at all should have been recorded. In 1961, R.M.Evans of the Kodak Research Laboratory showed that the red liquid transmitted ultraviolet radiation, and by an extraordinary coincidence many natural red dye-stuffs reflect ultraviolet. Thus the red separation was made on the basis of non-visible radiation rather than red, but the net result was correct and the projected images did give an identifiable reproduction of the original. Sutton's photographs enabled Maxwell to establish the validity of his theory and to provide the basis upon which all subsequent methods of colour photography have been founded.JW / BC -
19 Dancer, John Benjamin
SUBJECT AREA: Photography, film and optics[br]b. 1812 Englandd. 1887 England[br]English instrument maker and photographer, pioneer of microphotography.[br]The son of a scientific instrument maker, Dancer was educated privately in Liverpool, where from 1817 his father practised his trade. John Benjamin became a skilled instrument maker in his own right, assisting in the family business until his father's death in 1835. He set up on his own in Liverpool in 1840 and in Manchester in 1841. In the course of his career Dancer made instruments for several of the leading scientists of the day, his clients including Brewster, Dalton and Joule.Dancer became interested in photography as soon as the new art was announced in 1839 and practised the processes of both Talbot and Daguerre. It was later claimed that as early as 1839 he used an achromatic lens combination to produce a minute image on a daguerreotype plate, arguably the world's first microphotograph and the precursor of modern microfilm. It was not until the introduction of Archer's wet-collodion process in 1851 that Dancer was able to perfect the technique however. He went on to market a long series of microphotographs which proved extremely popular with both the public and contemporary photographers. It was examples of Dancer's microphotographs that prompted the French photographer Dagron to begin his work in the same field. In 1853 Dancer constructed a binocular stereoscopic camera, the first practicable instrument of its type. In an improved form it was patented and marketed in 1856.Dancer also made important contributions to the magic lantern. He was the first to suggest the use of limelight as an illuminant, pioneered the use of photographic lantern slides and devised an ingenious means of switching gas from one lantern illuminant to another to produce what were known as dissolving views. He was a resourceful innovator in other fields of instrumentation and suggested several other minor improvements to scientific apparatus before his working life was sadly terminated by the loss of his sight.[br]Further ReadingAnon., 1973, "John Benjamin Dancer, originator of microphotography", British Journal of Photography (16 February): 139–41.H.Gernsheim and A.Gernsheim, 1969, The History of Photography, rev. edn, London.JW -
20 Naßkollodiumverfahren
nt PRINT wet collodion processDeutsch-Englisch Wörterbuch für Informatik > Naßkollodiumverfahren
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См. также в других словарях:
wet collodion process — wet plate process, early photographic process in which a glass plate coated with an iodized collodion is dipped into a silver nitrate solution before use … English contemporary dictionary
wet collodion process — Photog. See wet plate process. * * * ▪ photography also called Collodion Process, early photographic technique invented by Frederick Scott Archer (Archer, Frederick Scott) of England in 1851. To a solution of collodion (cellulose… … Universalium
wet collodion process — Photog. See wet plate process … Useful english dictionary
wet plate process — wet collodion process, early photographic process in which a glass plate coated with an iodized collodion is dipped into a silver nitrate solution before use … English contemporary dictionary
wet plate process — a photographic process, in common use in the mid 19th century, employing a glass photographic plate coated with iodized collodion and dipped in a silver nitrate solution immediately before use. Also called wet collodion process, collodion process … Universalium
wet plate process — a photographic process, in common use in the mid 19th century, employing a glass photographic plate coated with iodized collodion and dipped in a silver nitrate solution immediately before use. Also called wet collodion process, collodion process … Useful english dictionary
Wet (collodion) process — Мокроколлодионный процесс … Краткий толковый словарь по полиграфии
Collodion process — An old deteriorated wet plate featuring Theodore Roosevelt The collodion process is an early photographic process. It was introduced in the 1850s and by the end of that decade it had almost entirely replaced the first practical photographic… … Wikipedia
wet-plate process — ˈ ̷ ̷| ̷ ̷ noun : an early collodion process … Useful english dictionary
collodion process — noun : a photographic process in which collodion is used as a vehicle for sensitive salts; specifically : an early process in which the negative is prepared by coating a glass plate with collodion containing iodide, exposing in a camera while wet … Useful english dictionary
collodion process — Photog. See wet plate process. [1865 60] * * * … Universalium