Abstract:For clarifying the microstructure evolution and macroscopic deformation mechanical quantitative behavior of lithium-ion battery electrode during calendering process, the morphological characteristics of electrode coating and current collector in the deformation zone were analyzed. The results show that the denseness of active particles significantly increase in the calendering direction, and the effect of calendering on electrode coating is summarized as carbon-PVDF compression, active particle fragmentation and fusion into secondary particles. The overall current collector has not been thinned. Due to the small hardness of graphite, the surface height of the copper foil fluctuates within 600 nm, and some of the active particles of the cathode electrode are embedded in the surface, with an embedding depth of 2 μm at the minimum thickness. Meanwhile, the coating compression is reduced to a plane deformation, and the deformation zone is distinguished into several microelements and force analysis by using the differential unit method and the compression deformation intrinsic model. Based on this, the calculation formulas of pressure distribution and rolling force were derived, and the relationship model between unit rolling force and coating thickness and compaction density is constructed, which can provide the theoretical basis for the implementation of accurate control of AGC thickness and process optimization.

Key words: lithium-ion battery electrode; calendaring; unit rolling force; microstructure; reduction rate