CFD Investigation into Internal Flows of PEM Fuel Cell for Optimal Performances

Zhi Jun Peng; Pattarapong Choopanya

doi:10.4028/www.scientific.net/AMR.724-725.757

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 724-725CFD Investigation into Internal Flows of PEM Fuel...

CFD Investigation into Internal Flows of PEM Fuel Cell for Optimal Performances

Abstract:

It is the objective of this study to present the 3-dimensional comprehensive computational fuel cell dynamics (CFCD) model of a scaled-down single PEM cell featuring a nominal active surface of 0.0004 m² for both conventional and serpentine flow field designs. The performance of these two designs are then analysed and compared keeping both anode and cathode inlet gases fully humidified. Then the parallel flow field was modelled under different inlet gas relative humidities (RH_a/RH_c) representing saturated, moderate, and dry conditions to observe the gain in cell performance. The higher pressure drop of the serpentine flow-field was demonstrated and the magnitude of which might seem to be negligible in the range of 100 Pascal. The simulation results show that a parallel flow-field design with appropriate humidity level can compete with the serpentine counterpart and gives considerably lower pressure drop across the cell. With a grid-independency analysis, it is suggested for the computational power available, the percentage error of important variables (species concentration and averaged current density) between the reference and finer mesh is negligible (< 3%) and the solution time is considerably less.

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Periodical:

Advanced Materials Research (Volumes 724-725)

Pages:

757-761

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.724-725.757

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Online since:

August 2013

Authors:

Zhi Jun Peng, Pattarapong Choopanya

Keywords:

CFD Simulation, Internal Flow Field, PEM Fuel Cell

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