Modeling of High Speed Remote Laser Cutting for Lithium-ion Batteries

This research investigates the underlying physics of the laser cutting of electrodes for lithium-ion batteries and validates important findings experimentally.The mathematical model considers heat transfer, mass transfer, fluid flow, melting, solidification, evaporation, kinetic Knudsen layers, multiple reflections, free surface evolution, and composite materials. The developed model is applied to the laser cutting of electrodes. Interesting simulation results near the material interface between current collectors and active electrode materials are observed. In addition, experimental results are presented. The kerf width of electrodes and composition change along the cut surface of electrodes are validated. The theoretical prediction shows a reasonable agreement with experimental observations. Moreover, the optimum range of laser parameters providing both high speed and high quality cutting are obtained.

Autorentext

Dongkyoung Lee is an assistant professor in the Department of Mechanical and Automotive Engineering at the Kongju National University, Korea. His research interest is to understand multi-physical phenomena during laser material interaction of multilayer composite. Furthermore, he is interested in fabricating bio materials using laser ablation