Effect of traveling-wave magnetic field on dendrite growth of high-strength steel slab: Industrial trials and numerical simulation

The dendrite growth behavior of high-strength steel during slab continuous casting with a traveling-wave magnetic field was studied in this paper. The morphology of the solidification structure and composition distribution were analyzed. Results showed that the columnar crystals could deflect and br...

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Bibliographic Details
Published in:International journal of minerals, metallurgy and materials metallurgy and materials, 2023-09, Vol.30 (9), p.1716-1728
Main Authors: Yao, Cheng, Wang, Min, Ni, Youjin, Wang, Dazhi, Zhang, Haibo, Xing, Lidong, Gong, Jian, Bao, Yanping
Format: Article
Language:English
Subjects:
Boundary layers
Ceramics
Characterization and Evaluation of Materials
Chemistry and Materials Science
Columnar structure
Composites
Composition
Continuous casting
Corrosion and Coatings
Crystals
Deflection
Dendrites
Electromagnetic forces
Equiaxed structure
Glass
High current
High strength steel
High strength steels
Liquid alloys
Low currents
Magnetic fields
Materials Science
Mathematical models
Metallic Materials
Natural Materials
Slab casting
Solidification
Surfaces and Interfaces
Temperature gradients
Thermal stress
Thin Films
Traveling waves
Tribology
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Summary:The dendrite growth behavior of high-strength steel during slab continuous casting with a traveling-wave magnetic field was studied in this paper. The morphology of the solidification structure and composition distribution were analyzed. Results showed that the columnar crystals could deflect and break when the traveling-wave magnetic field had low current intensity. With the increase in current intensity, the secondary dendrite arm spacing and solute permeability decreased, and the columnar crystal transformed into an equiaxed crystal. The electromagnetic force caused by the traveling-wave magnetic field changed the temperature gradient and velocity magnitude and promoted the breaking and fusing of dendrites. Dendrite compactness and composition uniformity were arranged in descending order as follows: columnar-to-equiaxed transition (high current intensity), columnar crystal zone (low current intensity), columnar-to-equiaxed transition (low current intensity), and equiaxed crystal zone (high current intensity). Verified numerical simulation results combined with the boundary layer theory of solidification front and dendrite breaking–fusing model revealed the dendrite deflection mechanism and growth process. When thermal stress is not considered, and no narrow segment can be found in the dendrite, the velocity magnitude on the solidification front of liquid steel can reach up to 0.041 m/s before the dendrites break.
ISSN:1674-4799
1869-103X
DOI:10.1007/s12613-023-2629-2