A Two-Dimensional, Two-Phase, Multicomponent, Transient Model for the Cathode of a Proton Exchange Membrane Fuel Cell Using Conventional Gas Distributors

A two-dimensional, two-phase, multicomponent, transient model was developed for the cathode of the proton exchange membrane fuel cell. Gas transport was addressed by multicomponent diffusion equations while Darcy's law was adapted to account for the capillary flow of liquid water in the porous gas diffusion layer. The model was validated with experimental results and qualitative information on the effects of various operating conditions and design parameters and the transient phenomena upon imposing a cathodic overpotential were obtained. The performance of the cathode was found to be dominated by the dynamics of liquid water, especially in the high current density range. Conditions that promote faster liquid water removal such as temperature, dryness of the inlet gas stream, reduced diffusion layer thickness, and higher porosity improved the performance of the cathode. There seems to be an optimum in the diffusion layer thickness at the low current density range. The model results showed that for a fixed electrode width, a greater number of channels and shorter shoulder widths are preferred. The transient profiles clearly showed that liquid water transport is the slowest mass-transfer phenomenon in the cathode and is primarily responsible for mass-transfer restrictions especially over the shoulder.

[1]  T. Nguyen,et al.  Two-phase flow model of the cathode of PEM fuel cells using interdigitated flow fields , 2000 .

[2]  S. Dutta,et al.  NUMERICAL PREDICTION OF TEMPERATURE DISTRIBUTION IN PEM FUEL CELLS , 2000 .

[3]  S. Dutta,et al.  Three-dimensional numerical simulation of straight channel PEM fuel cells , 2000 .

[4]  Sadik Kakac,et al.  Two‐dimensional model for proton exchange membrane fuel cells , 1998 .

[5]  T. Fuller,et al.  Influence of rib spacing in proton-exchange membrane electrode assemblies , 1996 .

[6]  Trung Van Nguyen,et al.  A Gas Distributor Design for Proton‐Exchange‐Membrane Fuel Cells , 1996 .

[7]  Supramaniam Srinivasan,et al.  Analysis of performance and of water and thermal management in proton exchange membrane fuel cells , 1995 .

[8]  T. Springer,et al.  Modeling and Experimental Diagnostics in Polymer Electrolyte Fuel Cells , 1993 .

[9]  Mark W. Verbrugge,et al.  A Mathematical Model of the Solid‐Polymer‐Electrolyte Fuel Cell , 1992 .

[10]  S. Srinivasan,et al.  Kinetics of Fuel Cell Reactions at the Platinum/Solid Polymer Electrolyte Interface , 1989 .

[11]  Ralph E. White,et al.  A finite difference procedure for solving coupled, nonlinear elliptic partial differential equations , 1987 .

[12]  L. A. Richards Capillary conduction of liquids through porous mediums , 1931 .

[13]  J. Newman,et al.  Mass Transport in Gas‐Diffusion Electrodes: A Diagnostic Tool for Fuel‐Cell Cathodes , 1998 .

[14]  Karl V. Kordesch,et al.  Fuel cells and their applications , 1996 .

[15]  Y. Rho Development and Performance of Gasketless Stack for Proton Exchange Membrane Fuel Cells , 1995 .

[16]  F. R. Foulkes,et al.  Fuel Cell Handbook , 1989 .