Multiphysics Simulation of Shell Solidification Evolution in CSP Thin Slab Casting of Silicon Steel with Box-Type Electromagnetic Stirring.

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Title: Multiphysics Simulation of Shell Solidification Evolution in CSP Thin Slab Casting of Silicon Steel with Box-Type Electromagnetic Stirring.
Authors: Xiao, Hong1 (AUTHOR), Liu, Jian1,2 (AUTHOR), Wang, Lang1,3 (AUTHOR), Wang, Sheng-Zhao1,2 (AUTHOR), Li, Yan-Zhong1,2 (AUTHOR), Wang, Pu3 (AUTHOR) wangpu@ncu.edu.cn
Source: Materials (1996-1944). Jun2026, Vol. 19 Issue 12, p2521. 21p.
Subjects: Solidification, Continuous casting, Computer simulation, Silicon steel, Crystal grain boundaries, Metal defects
Abstract: Highlights: B-EMS is innovatively applied to the high-speed CSP thin strip continuous casting production line, which solves the bottleneck of loading electromagnetic field on CSP production lines and effectively reduces the columnar grain ratio in the slabs. Multiphysics simulation reveals asymmetric electromagnetic forces generate unique width-directional flow patterns, accelerating superheat dissipation and intensifying solidification front scouring. Within the optimal current range, the solidified shell thickness increases by 2–3%. Industrial trials achieve a 30% increase in equiaxed grain ratio at 800 A, offering a practical solution for anisotropy-related defects. In CSP thin slab casting, high casting speeds promote excessive columnar grain growth, leading to low equiaxed grain ratios in non-oriented silicon steel and resulting in wrinkling defects. This study employs a box-type electromagnetic stirrer (B-EMS) to address this issue. A multiphysics model was established, in which grain transformation and its associated effects were neglected. The effects of B-EMS on the flow of molten steel, temperature distribution and evolution of solidified shell were analyzed, and industrial trials were conducted to verify the influence of B-EMS on grains. Results show that B-EMS generates asymmetric magnetic fields and electromagnetic forces, driving width-directional flow that enhances scouring of the solidification front. Compared with the experiment and simulation, the error in the magnetic field excited by B-EMS is within 5%. Under 800 A current, narrow-face center shell thickness increased from 22.88 mm (no stirring) to 23.62 mm (starting side) and 23.21 mm (pushing side). The central mushy zone area and liquid fraction decreased significantly, indicating accelerated solidification and more uniform shell growth. Industrial trials confirmed that the equiaxed grain ratio increased to approximately 30%, with significantly improved internal strand quality. This study demonstrates B-EMS's metallurgical effects in regulating solidification structure, optimizing shell morphology, and improving continuous casting slab quality. The numerical simulation can be correlated with the industrial production process to better guide manufacturing practices. [ABSTRACT FROM AUTHOR]
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Abstract:Highlights: B-EMS is innovatively applied to the high-speed CSP thin strip continuous casting production line, which solves the bottleneck of loading electromagnetic field on CSP production lines and effectively reduces the columnar grain ratio in the slabs. Multiphysics simulation reveals asymmetric electromagnetic forces generate unique width-directional flow patterns, accelerating superheat dissipation and intensifying solidification front scouring. Within the optimal current range, the solidified shell thickness increases by 2–3%. Industrial trials achieve a 30% increase in equiaxed grain ratio at 800 A, offering a practical solution for anisotropy-related defects. In CSP thin slab casting, high casting speeds promote excessive columnar grain growth, leading to low equiaxed grain ratios in non-oriented silicon steel and resulting in wrinkling defects. This study employs a box-type electromagnetic stirrer (B-EMS) to address this issue. A multiphysics model was established, in which grain transformation and its associated effects were neglected. The effects of B-EMS on the flow of molten steel, temperature distribution and evolution of solidified shell were analyzed, and industrial trials were conducted to verify the influence of B-EMS on grains. Results show that B-EMS generates asymmetric magnetic fields and electromagnetic forces, driving width-directional flow that enhances scouring of the solidification front. Compared with the experiment and simulation, the error in the magnetic field excited by B-EMS is within 5%. Under 800 A current, narrow-face center shell thickness increased from 22.88 mm (no stirring) to 23.62 mm (starting side) and 23.21 mm (pushing side). The central mushy zone area and liquid fraction decreased significantly, indicating accelerated solidification and more uniform shell growth. Industrial trials confirmed that the equiaxed grain ratio increased to approximately 30%, with significantly improved internal strand quality. This study demonstrates B-EMS's metallurgical effects in regulating solidification structure, optimizing shell morphology, and improving continuous casting slab quality. The numerical simulation can be correlated with the industrial production process to better guide manufacturing practices. [ABSTRACT FROM AUTHOR]
ISSN:19961944
DOI:10.3390/ma19122521