Joining of copper foils via Al/Ni reactive multilayer nanofoils

Interconnected individual battery cells of lithium batteries are unavoidably involved in joining in parallel to improve the battery capacity. Due to the advantage of the small joint area and short process time, micro resistance welding is one of common applied joining techniques of copper foils. However, strength improvement of micro resistance welded copper foils was restricted by the insufficient Joule heat accumulation at the faying interface. Here we used the exothermic reaction of Al/Ni reactive multilayer nanofoils as a local heat source at the faying interface of micro resistance welding of copper foils, designing to increase the heat accumulation and improve the joints strength. Two faying interfaces were formed at the joints of copper foils, one was at the thickness direction of AlNi reactants caused by the diffusion of Cu element based on the high temperature and fracture of coating layer, and another was formed at the surface of AlNi reactants and copper foils. Due to grain boundary relaxation, grain refining of AlNi alloy compound of final product with the average grain size of 27.9 nm at the faying interface attributed to the hardness increase and improvement of joints strength. The joints strength of two-layer copper foils increased to 100 N and the value was 500 N for the joints of multilayer copper foils with the assistance of Al/Ni reactive multilayer nanofoils. These results pave the way for the application of micro resistance welding technique in the battery cells joining of lithium batteries manufacture.

Automated summary

In this study, Al/Ni reactive multilayer nanofoils were used as a local heat source at the faying interface of micro resistance welding of copper foils, leading to an increase in joint strength. Grain boundary relaxation and Kirkendall effect resulted in grain refining of the AlNi alloy compound at the faying interface, contributing to the improvement of joint strength.