钛合金真空电弧重熔中稳定电弧循环的数值模拟

IF 2.6 3区物理与天体物理 Q2 PHYSICS, MULTIDISCIPLINARY

Physica Scripta Pub Date : 2024-08-11 DOI:10.1088/1402-4896/ad68d8

Mingyu Li, Lei Jia, Qingdong Miao, Wei Liu, Peng Zhao and Shufeng Yang

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引用次数: 0

摘要

通过利用数值模拟方法，分析了钛合金真空自耗熔炼过程中熔池的流动状态。研究了稳定电弧周期对熔池形状、枝晶臂间距、表面质量和收缩腔的影响。结果表明，在没有外部磁场的情况下，熔炼Φ720 毫米规格钛合金铸锭的熔池由自感磁力主导，导致熔体中心部分向下流动。仅 0.5 G 的杂散磁场就会导致埃克曼抽气，从而在芯部产生向上的二次流动以抵消杂散磁场。在外部磁场强度为 50 G 的情况下，选择 10 s-20 s 的周期可以实现相对稳定的双环流动模式。其熔池形状、枝晶臂间距和接触比均达到最佳性能，从而验证了双回路流动的可能性和可行性，模拟铸锭的宏观偏析与实验结果基本吻合，旨在为实际生产中的参数选择提供参考。

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Numerical simulation of arc stabilizing cycle in vacuum arc remelting of titanium alloy

Through utilizing numerical simulation methods, the flow state of the molten pool during the vacuum self-consumption melting process of titanium alloy was analyzed. The influence of the stable arc cycle on the shape of the molten pool, dendrite arm spacing, surface quality, and shrinkage cavity was examined. The results showed that without an external magnetic field, the molten pool for smelting a Φ720 mm specification titanium alloy ingot is dominated by self-inductance magnetic force, leading to a downward flow in the central part of the melt. A mere 0.5 G stray magnetic field can result in Ekman pumping, causing an upward secondary flow in the core to counteract it. At an externally added magnetic field strength of 50 G, choosing a 10 s-20 s cycle can achieve a relatively stable double loop flow pattern. The shape of its molten pool, dendrite arm spacing, and contact ratio all reach optimal performance, thus verifying the possibility and feasibility of the double loop flow, and the macroscopic segregation of the simulated ingots essentially matches the experimental results, aiming to provide references for selecting parameters in actual production.

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来源期刊

Physica Scripta 物理-物理：综合

CiteScore

3.70

自引率

3.40%

发文量

782

审稿时长

4.5 months

期刊介绍： Physica Scripta is an international journal for original research in any branch of experimental and theoretical physics. Articles will be considered in any of the following topics, and interdisciplinary topics involving physics are also welcomed: -Atomic, molecular and optical physics- Plasma physics- Condensed matter physics- Mathematical physics- Astrophysics- High energy physics- Nuclear physics- Nonlinear physics. The journal aims to increase the visibility and accessibility of research to the wider physical sciences community. Articles on topics of broad interest are encouraged and submissions in more specialist fields should endeavour to include reference to the wider context of their research in the introduction.