Enhancement of PEM Fuel Cell Performance by Flow Control

Vinh Nguyen Duy; Jung Koo Lee; Ki Won Park; Hyung Man Kim

doi:10.4028/www.scientific.net/MSF.804.75

Paper Titles

Biosorption of Strontium Ions by Low-Cost Sunflower Stem and Leaf
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Preparation and Characterizations of Novel Near Room-Temperature Driven Fe/Sr₂Bi₂O₅ Thermocatalyst
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Effects of Ultrafine Grinded Steel Slag Addition on Properties of Cement
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Effect of Calcium Compounds on Mechanical Properties of Eco-Friendly Non-Cement Mortar
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Enhancement of PEM Fuel Cell Performance by Flow Control
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A Comparative Study on the Physical Properties of Artificial Aggregates Made from Acid Clay and Dredged Soil
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Dust Removal Using Electrode-Plates Coated with Activated Carbon
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Effects of Nano-Porous Materials and Inert Gas on Sound Proof Properties of Double Layer Acryl Plate
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Characteristics of MSWI Ash and its Application to Zeolite Synthesis
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HomeMaterials Science ForumMaterials Science Forum Vol. 804Enhancement of PEM Fuel Cell Performance by Flow...

Enhancement of PEM Fuel Cell Performance by Flow Control

Abstract:

Flow-field design affects directly to the PEM fuel cell performance. This study aims to stimulate the under-rib convection by adding sub-channels and by-passes to the conventional-advanced serpentine flow-field to improve the PEM fuel cell performance. The experimental results show that if reacting gases flow in the same direction as the neighboring main channels, the under-rib convection shows a flow from the main channels to the sub-channels makes progress in reducing pressure drop and enhancing uniform gas supply and water diffusion. Alternatively, if in the direction opposite to that of the neighboring main channels, the under-rib convection shows a flow from the inlet side towards the outlet side across the sub-channel as in the conventional serpentine channels. Analyses of the local transport phenomena in the cell suggest that the inlet by-pass supplies the reacting gases uniformly from the entrance into the sub-channels and the outlet by-pass enhances water removal. Novel serpentine flow-field pattern employing sub-channels and by-passes shows uniform current density and temperature distribution by uniformly supplying the reacting gas. Furthermore, performance improvement of around 20% is observed from the experimental performance evaluation. As a result, longer battery life is expected by reducing the mechanical stress of membrane electrode assembly.