Abstract:The electromagnetic field, flow field and temperature field during the low voltage pulsed magnetic field direct chill casting of AZ80 magnesium alloy were simulated with finite element method, and the microstructure of the billet was observed by comparing those of billet by conventional direct chill (DC) casting process. The simulation results indicate that, during the low voltage pulsed magnetic field DC casting process, affected by electromagnetic force, forced convection and velocity vibration generate in the melt, leading to the reduced temperature grade of melt along the radial direction. The results show that the grains of the billet cast with low voltage pulsed magnetic are significantly refined and the tip of dendrite is rounded, compared with those of the conventional one. During the low voltage pulsed magnetic field DC casting process, the critical nucleation radius and critical nucleation energy near the crystallizer decrease, at the same time, the nuclei formed ahead the inner wall of crystallizer can be dispersed into the centre of the molten pool with the convection that caused by the pulsed magnetic field, which causes the increased nucleation rate. In addition, the growth of dendrite tip is inhibited by the passivation effect of the pulsed magnetic field, which leads to the grain refinement in the low voltage pulsed magnetic field direct chill casting billet.

Key words: magnesium alloy; low voltage pulsed magnetic field; direct chill casting; numerical simulation; grain refinement