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A coupled model of grain growth and solute transfer in molten pool of nickel-based alloy

A coupled model of grain growth and solute transfer in molten pool of nickel-based alloy
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摘要 A coupled model of grain growth and solute transfer based on cellular automaton ( CA ) method was established and applied to grain growth simulation in molten pool of nickel-based alloy. The CA method was used to simulate welding solidification process successfully, but few researches had taken the effect of convection on dendrite morphology into account. In this paper, solute transfer model was used to calculate the effect of convection and diffusion on solute field with CA method simulating grain growth. The results indicate that convection has a significant effect on the morphology of equiaxed grain. Dendrite growth in the upstream direction is amplified, while it is inhibited in the downstream direction. With inlet velocity increasing, this effect becomes more severe. A coupled model of grain growth and solute transfer based on cellular automaton ( CA ) method was established and applied to grain growth simulation in molten pool of nickel-based alloy. The CA method was used to simulate welding solidification process successfully, but few researches had taken the effect of convection on dendrite morphology into account. In this paper, solute transfer model was used to calculate the effect of convection and diffusion on solute field with CA method simulating grain growth. The results indicate that convection has a significant effect on the morphology of equiaxed grain. Dendrite growth in the upstream direction is amplified, while it is inhibited in the downstream direction. With inlet velocity increasing, this effect becomes more severe.
出处 《China Welding》 EI CAS 2009年第4期15-20,共6页 中国焊接(英文版)
基金 The research is supported by National Natural Science Foundation of China(50775112).
关键词 grain growth CONVECTION cellular automaton grain growth, convection, cellular automaton
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参考文献10

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