Influence of Operating and Electrochemical Parameters on PEMFC Performance: A Simulation Study

Proton exchange membrane fuel cell, or polymer electrolyte fuel cell, (PEMFC) has received a significant amount of attention for green energy applications due to its low carbon emission and less other toxic pollution capacity. Herein, we develop a three-dimensional (3D) computational fluid dynamic model. The values of temperature, pressure, relative humidity, exchange coefficient, reference current density (RCD), and porosity values of the gas diffusion layer (GDL) were taken from the published literature. The results demonstrate that the performance of the cell is improved by modifying temperature and operating pressure. Current density is shown to degrade with the rising temperature as explored in this study. The findings show that at 353 K, the current density decreases by 28% compared to that at 323 K. In contrast, studies have shown that totally humidified gas passing through the gas channel results in a 10% higher current density yield, and that an evaluation of a 19% higher RCD value results in a similar current density yield.

Automated summary

In this study, a three-dimensional computational fluid dynamic model was developed based on published literature data to investigate the impact of temperature and pressure on the performance of proton exchange membrane fuel cells. The results showed that the performance of the fuel cell can be enhanced by adjusting the temperature and operating pressure. It was also found that an increase in temperature leads to a decrease in current density, while fully humidified gas channels and higher reference current density values can improve current density.