A fully coupled three-dimensional, steady-state, two-fluid, multi-component and non-isothermal DMFC model has been developed in the commercial CFD package CFX 13 (ANSYS inc.). It accounts for the presence of micro porous layers, non-equilibrium phase change, and methanol and water uptake in the ionomer phase of the catalytic layer, and detailed membrane transport of methanol and water. In order to verify the models ability to predict methanol crossover, simulation results need to be compared with experimental measurements under different current densities along with air and methanol stoichiometries. Methanol crossover be indirectly measured based on the combined anode and cathode exhaust CO2 mole fraction and by accounting for the CO2 production at the anode as a function of current density. This approach is simple and assumes that all crossed over methanol is oxidized. Moreover, it takes CO2 crossover into account.

Volume Subject Area:
Modeling, Design, and Optimization for Low Temperature Fuel Cells
Topics:
Direct methanol fuel cells, Fluids, Methanol, Carbon dioxide, Anodes, Water, Accounting, Computational fluid dynamics, Current density, Equilibrium (Physics), Exhaust systems, Membranes, Simulation results, Steady state
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