Improved modeling and understanding of diffusion-media wettability on polymer-electrolyte-fuel-cell performance

Date Published
08/2010
Publication Type
Journal Article
Author
DOI
10.1016/j.jpowsour.2010.03.011
Abstract

A macroscopic-modeling methodology to account for the chemical and structural properties of fuel-cell diffusion media is developed. A previous model is updated to include for the first time the use of experimentally measured capillary pressure–saturation relationships through the introduction of a Gaussian contact-angle distribution into the property equations. The updated model is used to simulate various limiting-case scenarios of water and gas transport in fuel-cell diffusion media. Analysis of these results demonstrate that interfacial conditions are more important than bulk transport in these layers, where the associated mass-transfer resistance is the result of higher capillary pressures at the boundaries and the steepness of the capillary pressure–saturation relationship. The model is also used to examine the impact of a microporous layer, showing that it dominates the response of the overall diffusion medium. In addition, its primary mass-transfer-related effect is suggested to be limiting the water-injection sites into the more porous gas-diffusion layer.

Journal
Journal of Power Sources
Volume
195
Year of Publication
2010
Number
16
Pagination
5292-5304
Refereed Designation
Refereed
Organizations
Research Areas
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