Abstract A new elliptical groove gas diffusion layer (GDL) using a three-dimensional model is proposed to improve the transport properties of the GDL of a proton exchange membrane fuel cell (PEMFC). The effects of different shape parameters on water diffusion and transport behavior are investigated. The results revealed that compared with the traditional GDL, the presence of an elliptical groove greatly accelerates the flow rate of the reactants and products. Also, when the depth increases from 100 to 300 μm, the water mass fraction of the GDL decreases, whereas the oxygen mass fraction increases. As the radius increases, the low mass fraction area in GDL gradually increases, and the water mass fraction of the flow channel increases. As the spacing increases, the water mass fraction of the GDL in the xy-plane decreases, and the oxygen mass fraction increases. When the depth increases, the transport properties of the fuel cell are improved. All shape parameters contribute to the mean water mass fraction. The water mass fraction is the lowest when depth is 350 μm, radius is 350 μm, width is 200 μm, and spacing is 50 μm.

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