Effects of geometrical parameters on the performance of hydrogen regenerative pumps in proton exchange membrane fuel cell systems.

Regenerative pumps are considered a promising option for hydrogen recirculation in proton exchange membrane fuel cell (PEMFC) systems. The geometry of the impeller exerts a direct influence on the pressurization process within the regenerative pumps. However, the influence has not been explored systematically in any available publications. This study investigates the effects of geometric parameters on pump performance and provides design guidelines for hydrogen regenerative pumps. A three-dimensional (3D) numerical model is developed and validated. The effects of critical geometric parameters, including the number of blades, impeller radius, and impeller radius ratio, on the performance of the regenerative pumps are then analyzed. Based on the analysis, this work recommends 35 blades and an impeller radius ratio of 0.65. To establish a correlation between operational performance and micro-flow mechanisms, the fluid velocity distribution at the interface of the rotating and stationary domains is quantitatively analyzed. Results indicate that a reduction in the flow rate results in increased axial velocity and decreased tangential velocity. The increased axial velocity enhances mass transfer, thus increasing the pressure and diminishing the efficiency, whereas the decreased tangential velocity intensifies the impact of the fluid on the blades, leading to increased shock losses and reduced efficiency. • The effects of the number of blades, impeller radius, and impeller radius ratio on the performance of hydrogen regenerative pumps are revealed. • The optimal values of the number of blades and impeller radius ratio are proposed. • The fluid flow velocities at the interface of rotating and stationary domains are quantitatively analyzed. • The flow mechanism of regenerative machines is elucidated through numerical methods. [ABSTRACT FROM AUTHOR]