Solid oxide fuel cells (SOFCs) offer many potential benefits as an energy conversion device. This paper addresses experimental validation of a numerical SOFC model that has been developed. Results are compared at steady state operation for temperatures ranging from 1073 K to 1173 K and for H2 gas concentrations fuel supplies of 10–90% with a balance of N2. The results agree well with a maximum of 13.3% difference seen between the numerical and experimental results, which is within the limit of the experimental uncertainties and the material constants that are measured, with most comparisons well below this level. It is concluded that since the model is very sensitive to material properties and temperature that for the best results they should be as specific as possible to the experiment. These specific properties were demonstrated in this paper and a validation of a full fuel cell model, with a concentration on the anode, was presented.

Issue Section:
Research Papers
Keywords:
solid oxide fuel cell, model, experimental performance, validation, air independent, solid oxide fuel cells
Topics:
Solid oxide fuel cells, Steady state, Temperature, Fuels, Modeling, Anodes, Fuel cells
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