期刊
FUEL
卷 339, 期 -, 页码 -出版社
ELSEVIER SCI LTD
DOI: 10.1016/j.fuel.2022.126975
关键词
Hydrogen energy; Energy efficiency; Fuel cell; Sustainable energy; Water management
This study presents a new flow field design based on the shape and reflex similarity of circulatory systems. The design includes intermediate reservoirs to collect and distribute flow channels and allow intermediate feedings. Applied to a proton exchange membrane fuel cell, this design outperforms a conventional serpentine flow channel with higher power density. Various feeding arrangements were also examined, and the case of 70%, 20%, and 10% symmetrical feeding at the main and intermediate inlets showed the highest performance with a 38% higher power density compared to the serpentine flow field.
This study presents the design principles and details of a new flow field based on the shape and reflex similarity of the circulatory systems of living things. This design has intermediate reservoirs that collect and distribute the flow channels and also allow for intermediate feedings. This design is applied to a proton exchange membrane fuel cell, and its performance is tested and compared with a conventional serpentine type of flow channel. The novel fuel cell with intermediate reservoirs reaches a current density of 0.171 A/cm2 at 0.406 V and displays a power density 10 % higher than the serpentine flow field. Moreover, eleven cases involving symmetrical and asymmetrical feeding arrangements are also examined. The case of 70 %, 20 % and 10 % symmetrical feeding at the main and intermediate inlets shows the highest performance by providing a 38 % higher power density compared to the serpentine flow field.
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