| METALS AND METAL MATRIX COMPOSITES |
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| Precipitation Mechanism of Sulfide in Non-oriented Silicon Steel |
| QIAO Jialong1, GUO Feihu1, FU Bing2, HU Jinwen1,3, XIANG Li1, QIU Shengtao1
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1 National Engineering Research Center of Continuous Casting Technology, China Iron & Steel Research Institute Group, Beijing 100081, China
2 State Key Laboratory of Refractories and Metallurgy, Wuhan University of Science and Technology, Wuhan 430081, China
3 School of Metallurgy and Resources, Anhui University of Technology, Maanshan 243002, China |
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Abstract The precipitation mechanism of sulfide and the effect of sulfide on grain growth during annealing in non-oriented silicon steel were systematically studied based on the calculation of thermodynamics and kinetics, combined with scan electron microscopy (SEM) and transmission electron microscopy (TEM). The results indicate that sulfides in non-oriented silicon steel are mainly (Mn,Cu)S composite precipitates. In the solidification process, MnS and Cu2S would not possess the precipitation thermodynamic conditions. MnS would preferentially nucleate at grain boundaries before Cu2S, and dislocation nucleation will dominate as the temperature decreases. In the soaking process, MnS in w(Si+Al)≥2.5% non-oriented silicon steel and Cu2S in w(Si+Al)≤1.6% non-oriented electrical steel are mainly nucleated at the grain boundary. Meanwhile, during the soaking process the precipitation amount of MnS is much larger than that of Cu2S in the grain boundary, and Cu2S would mainly precipitate in the subsequent heat treatment processes. Ostwald ripening calculations of MnS and Cu2S show that the effect of MnS and Cu2S in w(Si+Al)≥2.5% non-oriented silicon steel on grain growth is significantly greater than that of w(Si+Al)≤1.6% non-oriented electrical steel.
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Published: 12 November 2021
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| Fund:National Key Research and Development Plan (2016YFB0300305). |
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Corresponding Authors:
qiustchina@126.com
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About author:: Jialong Qiao, Ph.D. student of National Engineering Research Center of Continuous Casting Technology, China Iron & Steel Research Institute Group, focusing on the research of silicon steel quality improvement, process optimization and theories.
Shengtao Qiu, senior engineer of National Engineering Research Center of Continuous Casting Technology, China Iron & Steel Research Institute Group, mainly engaged in research and development of basic theory and technology of metallurgical materials technology, including mathematical simulation of metallurgical processes, application of electromagnetic technology in continuous casting process, homogenization of conti-nuous casting billet and quality control of casting billet, high-quality steel (electrical steel, pressure vessels, ship plates, etc.) production technology. |
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2021, Vol. 35 
