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http://dx.doi.org/10.5229/JKES.2012.15.2.74

Design of Serpentine Flow-field Stimulating Under-rib Convection for Improving the Water Discharge Performance in Polymer Electrolyte fuel cells  

Choi, Kap-Seung (Industrial Technology Cooperation Center, Korea Institute of Energy Research)
Bae, Byeong-Cheol (Department of Mechanical and Automotive Engineering & High Safety Vehicle Core Technology Research Center, INJE University)
Park, Ki-Won (Department of Mechanical and Automotive Engineering & High Safety Vehicle Core Technology Research Center, INJE University)
Kim, Hyung-Man (Department of Mechanical and Automotive Engineering & High Safety Vehicle Core Technology Research Center, INJE University)
Publication Information
Journal of the Korean Electrochemical Society / v.15, no.2, 2012 , pp. 74-82 More about this Journal
Abstract
Proton exchange membrane fuel cell performance is changed by the complicated physical phenomenon. In this study, water discharge performance of proton exchange membrane fuel cell were performed numerically to compare serpentine channel flow fields of 5-pass 4-turn serpentine and 25 $cm^2$ reaction surface between with and without sub-channel at the rib. Through the supplement of sub channel flow field, it is shown from the results that water removal characteristic inside channel improves because the flow direction of under-rib convection is changed into the sub channel. Reacting gases supplied from entrance disperse into sub channel flow field and electrochemical reaction occurs uniformly over the reaction surface. The results obtained that total current density distributions become uniform because residence time of reacting gases traveling to sub-channel flow field is longer than to main channel.
Keywords
Polymer Electrolyte Fuel Cell; Serpentine Flow-Field; Sub-Channel; Under-Rib Convection; Water Discharge Performance;
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