Numerical simulation and experimental investigation on thermal characteristics during induction diffusion welding of Cu/Al dissimilar metals

The quality of copper-aluminum welding has a crucial impact on the safety and reliability of power battery connection plates and busbars. A new welding method, Induction Diffusion Welding (IDW), was studied to investigate the effects of working condition parameters such as power supply variations on the welding process. Additionally, the spatial distribution of electromagnetic and temperature fields was analyzed. The research results indicate that the power output has the most significant impact on magnetic flux density. Increasing the power from 25 kW to 45 kW results in an accelerated decrease rate of about 35 % in magnetic flux density, with a final decrease of about 30 % in magnetic flux density value. An increase in power input and heating duration helps to increase the maximum temperature and improve temperature uniformity. Power supply is a key factor determining the rate of temperature rise and temperature stabilization time. At 35 kW, the balance between heat generation and heat dissipation results in the shortest temperature stabilization period and the smallest cross-layer temperature gradient, with uniformity reaching a maximum of 97 %, an increase of 6.08 % and 1.32 % compared to 25 kW and 45 kW, respectively. The simulated maximum temperature variation and heat-affected zone distribution are in excellent agreement with experimental observations, thus verifying the accuracy and feasibility of the simulation model.