Flow Field Analysis and Performance Study of a Hydrogen Circulation Pump for Proton Exchange Membrane Fuel Cell Vehicles with Different Working Clearances

This study investigates the impact of working clearances on the internal flow field, pressure pulsations, flow pulsations, and radial forces experienced by a hydrogen circulation pump. Numerical calculations are conducted on seven sets of distinct working clearances for the pump. The research findings demonstrate that an increase in meshing clearance and radial clearance results in higher leakage flow rate during the compression exhaust process, leading to a decrease in hydrogen circulation pump's exhaust flow rate. When the meshing clearance increases from 0.15 to 0.21 mm, the actual exhaust flow rate of the pump decreases from 37.46 to 32.73 m3h−1. Similarly, when the radial clearance increases from 0.18 to 0.24 mm, the actual exhaust flow rate of the pump decreases from 42.46 to 29.71 m3h−1. Additionally, with an increase in meshing clearance, both the radial forces Fxand Fyof the active rotor exhibit a downward trend. Yet, as radial clearance grows, the radial force Fxslightly descends, while the change trend of radial force Fyis first positive decrease and then reverse increase. The hydrogen circulating pump is an important component of the hydrogen fuel cell system, playing a crucial role in the recycling of hydrogen energy. This article investigates the impact of different clearances on pump performance . Additionally, the distribution of radial forces and pulsation characteristics between the active and driven rotors are analyzed as well.