连铸
布鲁姆
机制(生物学)
选择(遗传算法)
材料科学
铸造
交流电
机械工程
冶金
复合材料
声学
机械
工程类
计算机科学
物理
光学
电气工程
人工智能
电压
量子力学
作者
Tao Wang,Xiaobing Zhang,Wen Wang,Zhang Yan,Jinhui Xu,Yue Fei,Yaogong Wang,Ningning Liu
标识
DOI:10.1002/srin.202500018
摘要
A coupled multiphysics model involving electromagnetic, fluid flow, solidification, and heat transfer is developed to investigate the alternating final helical electromagnetic stirring (F‐HEMS). The postprocessing is used to apply the Q ‐criterion to extract the rotating fluid's mesh and evaluate the alternating configuration of F‐HEMS. The results show that the alternating stirring mechanism is the rotating fluid's fragmentation and reorganization. Alternating stirring requires pause stirring, as incorporating pause stirring leads to greater stirring depth. Moreover, when stirring is paused, the rotating fluid dissipates within 18 s. Regardless of the specific pause duration, the volume of the rotating fluid consistently reaches a stable value at 55 s, which suggests that multiple cycles are necessary for effective alternating stirring. In addition, the optimal pause duration is determined to be 5 s. After the pause stirring, the stirring direction should be opposite to the original direction; opposite stirring results in a larger stirring volume, width, and depth. In the plant trials, the alternating F‐HEMS configuration derived from the numerical simulations is applied, leading to favorable results in the macrostructure of the strand. Although the alternating F‐HEMS is still an emerging technology, determining the alternating configuration and mechanism significantly contributes to its practical application.
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