Effect of cold-rolling deformation and rare earth yttrium on microstructure and texture of oriented silicon steel

Effect of cold-rolling deformation and rare earth yttrium on microstructure and texture of oriented silicon steel

In order to study the effect of cold-rolling deformation and rare earth Y on the microstructure and texture of 3.0% Si-oriented silicon steel, the microstructure and texture of cold-rolled oriented silicon steel with 60, 72, and 86% deformation are analyzed using electron backscatter diffraction and...

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Bibliographic Details
Published in:High temperature materials and processes Vol. 42; no. 1; pp. pp. 78 - 81
Main Authors: Guo, Zhihong, Liu, Pengjun, Zheng, Yaxu, Zhu, Liguang, Zhang, Yuanxiang, Sun, Huilan, Li, Xiangyang, Liu, Yu, Cao, Ruifang
Format: Journal Article
Language:English
Published: Berlin De Gruyter 15-02-2023
Walter de Gruyter GmbH
Subjects:
Cold
Cold rolling
Deformation analysis
Deformation effects
Earth
Edge dislocations
Electron backscatter diffraction
Grains
Image analysis
Inclusions
Microstructure
Misalignment
Nucleation
oriented silicon steel
rare earth Y
Shear bands
Sheets
Silicon steels
Texture
Yttrium
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Summary:In order to study the effect of cold-rolling deformation and rare earth Y on the microstructure and texture of 3.0% Si-oriented silicon steel, the microstructure and texture of cold-rolled oriented silicon steel with 60, 72, and 86% deformation are analyzed using electron backscatter diffraction and image analysis software. The experimental results show that the deformation band becomes narrower and the distribution of shear bands becomes denser with increasing cold-rolling deformation. Compared to the Y-free steel, cold-rolled sheet containing rare earth Y has greater shear bands. The pinning effect of rare earth Y hinders the dislocation movement, which leads to the increase of kernel average misorientation value and shear bands. With the increase of cold-rolling deformation, the texture concentrates on α and λ. This is mainly due to the change from {100} 〈001〉 to {001} 〈110〉, intensifying λ texture, and the change from {111} 〈112〉 to {111} 〈110〉, thus strengthening the α texture. The texture strength of cold-rolled sheets can be decreased by rare earth Y. But the γ texture strength in cold-rolled sheets containing Y is significantly higher than in those without Y. The γ texture strength can reach up to 7.3, and the strong points are mainly {111} 〈112〉. This is because the number of inclusions in steel increases with the addition of rare earth Y. In the process of grain nucleation, the {111} oriented grains nucleate heterogeneously on the inclusions. It forms a large number of {111} oriented grains and improves the γ texture strength.
ISSN:2191-0324
0334-6455
2191-0324
DOI:10.1515/htmp-2022-0258