A Coupled Magnetohydrodynamics (MHD) and Thermal Stress-Strain Model to Explore the Impact of Gas Cooling on Ingot Solidification Shrinkage in Vacuum Arc Remelting (VAR) Process

J. Bohacek, E. Karimi-Sibaki, A. Vakhrushev, K. Mraz, J. Hvozda, M. Wu, A. Kharicha
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Abstract

An advanced 2D axisymmetric magnetohydrodynamics model, including calculations for electromagnetic, thermal, and flow fields, fully coupled with a thermal stress-strain model, allowing the computation of solid mechanical parameters like stress, strain, and deformation within the ingot of the vacuum arc remelting process is presented. This process encounters challenges due to solidification shrinkage, which causes losing contact between the ingot and the mold, reducing the cooling efficiency of the system, resulting in a deeper melt pool and decreasing ingot quality. Herein, the width of the air gap along the ingot, the precise position of contact between the ingot and mold, and the profile of the melt pool, affected by gas cooling, are calculated. The global pattern of transport phenomena, such as (electro-vortex) flow and electromagnetic fields in the bulk of the ingot, is insensitive to helium gas cooling through the shrinkage gap. However, including gas cooling significantly improves heat removal through the mold, which consequently reduces the pool depth of the Alloy 718 ingot, leading to an improvement in the quality of the ingot.

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探索真空电弧重熔 (VAR) 过程中气体冷却对铸锭凝固收缩影响的磁流体动力学 (MHD) 和热应力-应变耦合模型
本文介绍了一种先进的二维轴对称磁流体动力学模型,包括电磁场、热场和流场计算,并与热应力应变模型完全耦合,可计算真空电弧重熔工艺中铸锭内的应力、应变和变形等固体机械参数。由于凝固收缩会导致钢锭与模具之间失去接触,从而降低系统的冷却效率,导致熔池变深和钢锭质量下降,因此该工艺面临着挑战。在此,我们计算了受气体冷却影响的钢锭气隙宽度、钢锭与模具之间接触的精确位置以及熔池剖面。钢锭主体中的(电涡)流和电磁场等传输现象的整体模式对通过收缩间隙进行的氦气冷却不敏感。然而,通过气体冷却可明显改善模具的散热,从而减少合金 718 铸锭的熔池深度,提高铸锭的质量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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