Experimental investigation of the effect of bioinspired flow field design on polymer electrolyte membrane fuel cell.

Flow fields are a primary component of polymer electrolyte membrane fuel cells (PEMFCs), the components supplying fuel cells with reactant gases, such as hydrogen and oxygen. However, the flow fields of fuel cells are limited by the nonuniform poor distribution of reactant gases, unintended pressure drop across channels, and poor water management, among other issues. Thus, relevant designs must focus on obtaining the lowest possible pressure drop while attaining the best possible distribution of reactant gases, further improving cell performance. In this work, the impact of novel bioinspired flow field designs on PEMFC performance was investigated. Three flow field configurations, namely, sunflower-inspired flow field (SUFF), flower of life-inspired flow field (FLFF), and palm frond-inspired flow field (PAFF), were designed, as inspired by the shape of the sunflower (i.e., flower of life and palm frond). Results revealed that the optimal operating conditions for the fuel cell were 1 L/min and 1.1 bar. The bioinspired configurations significantly affected PEMFC performance at a low voltage (< 0.645 V), but the impact was negligible at a high voltage (> 0.645 V). Furthermore, the ohmic loss region and the concentration loss region were both significantly improved by the bioinspired designs. The maximum power density was significantly increased for SUFF, FLFF, PAFF1, and PAFF2 by 16.84%, 6.07%, 6.32%, and 10.40%, respectively. [ABSTRACT FROM AUTHOR]