Performance of unit PEM fuel cells with a leaf-vein-simulating flow field-patterned bipolar plate

This study was conducted to investigate the performance of 25-cm2-unit polymer electrolyte fuel cells, the bipolar plate of which has a flow field that simulates leaf veins. The test flow fields were serpentine, parallel, and net leaf flow fields mimicking ginkgo and dicotyledonous leaves. The maxim...

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Bibliographic Details
Published in:International journal of hydrogen energy 2019-09, Vol.44 (43), p.24036-24042
Main Authors: Kang, Hie Chan, Jum, Kyung Min, Sohn, Young Jun
Format: Article
Language:English
Subjects:
Biomimicry
Bipolar plate
Flow field
Fuel cell
Power density
Water management
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Summary:This study was conducted to investigate the performance of 25-cm2-unit polymer electrolyte fuel cells, the bipolar plate of which has a flow field that simulates leaf veins. The test flow fields were serpentine, parallel, and net leaf flow fields mimicking ginkgo and dicotyledonous leaves. The maximum power density for the ginkgo flow field was 7% lower than that for the serpentine flow field, and 40% higher than that for the parallel flow field under normal operating conditions. However, the air-feeding power required by the ginkgo was only 3% of that required by the serpentine. The usable power density for the ginkgo flow field was the highest among all flow fields. Additionally, the water-removal capability of the ginkgo flow field was superior to that of the parallel and net leaf flow fields, but inferior to that of the serpentine flow field. Furthermore, the amount of water remaining in the flow field channels was found to be correlated to the length of the unit channel. Therefore, the ginkgo pattern can be considered to be an optimal flow field design for the fuel cell. •The ginkgo flow field mimics the veins of a ginkgo leaf.•The ginkgo flow field is superior in usable power to the conventional flow fields.•The air fan power used by the ginkgo flow field is 3% of that of the serpentine.•The ginkgo flow field removes more water than the parallel flow field.•The longer the unit channel, the greater the water removal.
ISSN:0360-3199
1879-3487
DOI:10.1016/j.ijhydene.2019.07.120