Transport Rate of Liquid Water and Saturated Water Vapors across Polymer Proton-Exchange Membranes

Dependences of the transport rate of liquid water and saturated water vapor across commercial membranes (Nafion, MF-4SK) and proton-exchange membranes synthesized by the authors (PVDF, PP, UHMWPE, PTFE films modified with sulfonated polystyrene) on the membrane thickness have been studied. It has be...

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Published inPetroleum chemistry Vol. 58; no. 6; pp. 496 - 502
Main Authors Kritskaya, D. A., Abdrashitov, E. F., Bokun, V. Ch, Ponomarev, A. N., Sanginov, E. A., Dobrovolsky, Yu. A.
Format Journal Article
LanguageEnglish
Published Moscow Pleiades Publishing 01.06.2018
Springer
Springer Nature B.V
Subjects
Chemistry
Chemistry and Materials Science
Exchanging
Flow resistance
Industrial Chemistry/Chemical Engineering
Membranes
Polyethylenes
Polymers
Polystyrene resins
Proton exchange membrane fuel cells
Protons
Transport rate
Vapor phases
Water
Water vapor
proton-exchange membranes
liquid water permeability
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Summary:Dependences of the transport rate of liquid water and saturated water vapor across commercial membranes (Nafion, MF-4SK) and proton-exchange membranes synthesized by the authors (PVDF, PP, UHMWPE, PTFE films modified with sulfonated polystyrene) on the membrane thickness have been studied. It has been found that at room temperature (17–25°C), the transport rate of liquid water and saturated water vapor across the membranes into an air stream hardly depends on the membrane type and thickness (60–240 μm), with the transport rate of saturated vapor being almost an order of magnitude below that of liquid water contacting one of the membrane surfaces. The fact that the flux of water and water vapor across the membrane does not depend on membrane thickness under conditions of maximum moistening suggests that the flow resistance is determined by the resistance at the feed and permeate interfaces. If one of the membrane surfaces is in contact with liquid water, the transport rate is equal to the rate of water removal from the permeate surface of the membrane; in the case of contact with saturated vapor, the transport rate is determined by the rate of water sorption from the vapor phase by the membrane. The results can be used to optimize the operation of fuel cells based on polymer proton-exchange membranes.
ISSN:0965-5441
1555-6239
DOI:10.1134/S0965544118060063