枝晶(数学)
凝聚态物理
格子Boltzmann方法
物理
磁场
洛伦兹力
各向异性
机械
磁流体力学
对流
合金
垂直的
定向凝固
材料科学
领域(数学)
旋转磁场
格子(音乐)
不对称
流量(数学)
身体力量
磁性形状记忆合金
联轴节(管道)
微观结构
磁各向异性
磁致伸缩
作者
Qing An Huang,Yinqi Qiu,Mengwu Wu,Xunpeng Qin
摘要
As a non-contact external field regulation technology, magnetic-field-assisted forming demonstrates significant process advantages and application potential in the field of liquid metal forming. This study established a magnetohydrodynamics multi-scale coupling model based on the phase-field and lattice Boltzmann method. The anisotropy of solute transport behavior during the solidification of Al-Cu alloy under the influence of a magnetic field and its regulatory mechanism on dendrite morphology were investigated. The results indicate that a magnetic field oriented perpendicular to the convection direction inhibits inertia-dominated melt flow through Lorentz force effects. This action diminishes solute distribution asymmetry and facilitates the transition of dendrite morphology from a convection-deflected state to one dominated by diffusion. A transverse magnetic field can suppress gravity-driven solute plumes, thereby eliminating differences in growth rates at dendrite tips induced by natural convection and promoting nearly symmetric dendrite growth. An inclined magnetic field influences the preferred orientation of secondary dendrite arms by altering melt flow direction while accelerating interface instability. Moreover, varying intensities and orientations of the magnetic field can optimize uniformity in solidification microstructure by reconstructing flow field distributions and mitigating solute enrichment as well as the flow field distortion among dendrites.
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