Simulation of binary gas separation in hollow fiber membrane-acetylene dehydration

Desalination

Volumn 233, Issue 1-3, 2008, Pages 310-318

  Zhao, Suying ^a   Li, Zhiqiang ^a   Liu, Yi ^a   Wang, Liang'en ^a  

^a FUZHOU UNIVERSITY   (China)

Author keywords

Acetylene; Concentration polarization; Dehydration; Hollow fiber membrane; Simulation

Indexed keywords

ACETYLENE; CAPILLARITY; COMPOSITE MEMBRANES; CONCENTRATION (PROCESS); DEHYDRATION; DEWATERING; FIBERS; GASES; ISOMERS; LIGHTING; LIQUIDS; MATHEMATICAL MODELS; MEMBRANES; OPTICAL SENSORS; POLARIZATION; SEPARATION; SEPARATORS; VAPORS; WATER VAPOR;

BINARY GASES; BOUNDARY RESISTANCES; CONCENTRATION POLARIZATION; CONCENTRATION POLARIZATIONS; DIFFERENTIAL UNITS; EXPERIMENTAL DATUM; FEED GASES; FEED SIDES; HOLLOW FIBER COMPOSITE MEMBRANES; HOLLOW FIBER MEMBRANE; HOLLOW FIBERS; INDUSTRIAL GASES; MEMBRANE SEPARATION PROCESSES; RESISTANCE MODELS; RETENTATE; SEPARATION FACTORS; SIMULATED RESULTS; SIMULATION; VAPOR COMPOSITIONS; VAPOR PARTIAL PRESSURES;

GAS PERMEABLE MEMBRANES;

ACETYLENE; CONCENTRATION (COMPOSITION); DEHYDRATION; MEMBRANE; NUMERICAL MODEL; PERMEABILITY; POLARIZATION; SEPARATION; WATER VAPOR;

EID: 54449096132     PISSN: 00119164     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.desal.2007.09.056     Document Type: Article

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