Citation: | ZHANG Xinchun, WANG Junyu, WANG Yulin, HUANG Zixuan, WANG Kai, QIN Jiangyi. Impact Responses of Prismatic Lithium-Ion Battery Based on the Membrane Factor Method[J]. Applied Mathematics and Mechanics, 2022, 43(11): 1203-1213. doi: 10.21656/1000-0887.430289 |
Aimed at the internal short circuit problem due to large deformation of the prismatic lithium-ion battery cell under impact loadings, a simplified battery model was first established. Then the motion equations of velocity and displacement based on the membrane factor method were proposed. With the effects of the face-sheet thickness and the densification region on the normalized final deflection, impact response characteristics of prismatic battery cells were investigated in detail. The results show that, the improved motion equations involving the membrane factor can reflect the dynamic response mechanisms of the prismatic battery cell under impact loadings, and the large deflection under high-speed impact can be predicted. With the increase of the face-sheet thickness, the deflection of the battery cell’s lower part decreases obviously. However, the densification region expands with the face-sheet thickness. The deflection and the densification region of the cell’s lower part both increase with the inner core density of the battery. This proposed impact model provides a theoretical guidance for the multi-functional integrated dynamic design of prismatic battery cells.
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