Effect of Primary Annealing Temperature on Primary and Secondary Recrystallization in Strip-Cast Grain-Oriented Silicon Steel

Xiang Lu; Meng Fei Lan; Feng Fang; Y.X. Zhang; Yang Wang; Guo Yuan; Wei Na Zhang; Guo Dong Wang

doi:10.4028/www.scientific.net/MSF.944.199

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HomeMaterials Science ForumMaterials Science Forum Vol. 944Effect of Primary Annealing Temperature on Primary...

Effect of Primary Annealing Temperature on Primary and Secondary Recrystallization in Strip-Cast Grain-Oriented Silicon Steel

Abstract:

Grain-oriented silicon steel was produced by strip casting route. The effect of different annealing temperature on primary annealing and secondary annealing was investigated. The result showed that the average grain diameter increased and the grain uniformity was gradually destroyed with the increasing annealing temperature. Regardless of annealing temperature, the primary texture consisted of strong γ-fiber and weak λ-fiber. With the increase of annealing temperature, the γ-fiber intensity increased. In addition, the Goss component was not shown at 780-880 °C but appeared at 980 °C. After secondary annealing, complete abnormal grain growth occurred in all samples and the average grain diameter increased with the primary annealing temperature. The Goss sharpness of secondary grains firstly increased and then decreased with a peak value obtained at 830 °C. This result was explained in terms of the combination of the inhibiting force, primary grain diameter and primary texture.

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Periodical:

Materials Science Forum (Volume 944)

Pages:

199-204

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.944.199

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Online since:

January 2019

Authors:

Xiang Lu*, Meng Fei Lan, Feng Fang, Y.X. Zhang, Yang Wang, Guo Yuan, Wei Na Zhang, Guo Dong Wang

Keywords:

Grain-Oriented Silicon Steel, Microstructure, Secondary Annealing, Strip-Cast, Texture

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References

[1] M.F. Littman, J. Magn. Magn, Mater, 26 (1982) 1-10.

Google Scholar

[2] Z.S. Xia, Y.L. Kang, Q.L. Wang, J. Magn. Magn, Mater,320 (2008) 3229-3233.

Google Scholar

[3] Y. Wang, Y.B. Xu, Y.X. Zhang, F. Fang, X. Lu, H.T. Liu, G.D. Wang, J. Magn. Magn, Mater, 379 (2015) 161-166.

Google Scholar

[4] H.Y. Song, H.T. Liu, H.H. Lu, L.Z. An, B.G. Zhang, W.Q. Liu, G.M. Cao, C.G. Li, Z.Y. Liu, G.D. Wang, Mater. Lett, 137 (2014) 475-478.

Google Scholar

[5] X. Lu, Y.B. Xu, F. Fang, Y.X. Zhang, Y. Wang, H.T. Jiao, G.M. Cao, C.G. Li, G. Yuan, G.D. Wang, J. Magn. Magn. Mater, 404 (2016) 230-237.

Google Scholar

[6] J.Y. Park, K.S. Han, J.S. Woo, S.K. Chang, N. Rajmohan, J.A. Szpunar, Acta Mater, 50 (2002) 1825-1834.

Google Scholar

[7] Y. Sha, F. Zhang, S. Li, X. Gao, J. Xu, L. Zuo, J. Mater. Sci. Tech, 20 (2004) 253-256.

Google Scholar

[8] J.L. Jia, L.H. Liu, W. Shi, X.L. Wu, L.J. Li, Q.J. Zhai, Mater. Sci. Tech, 27 (2011) 1475-1481.

Google Scholar

[9] M.A.D. Cunha, S.C. Paolinelli, Mater. Res, 5 (2002) 373-378.

Google Scholar

[10] D. Moseley, Y. Hu, V. Randle, T. Irons, Mater. Sci. Eng, A 392 (2005) 282-291.

Google Scholar

[11] X. Lu, F. Fang, Y. Zhang, Y. Wang, G. Yuan, Y. Xu, G. Cao, R.D.K. Misra, G. Wang, Steel Res. Int, 88 (2016) 1-10.

Google Scholar

[12] J. Barros, T. Ros-Yanez, L. Vandenbossche, L. Dupre, J. Melkebeek, Y. Houbaert, J. Magn. Magn. Mater, 290 (2005) 1457-1460.

Google Scholar

[13] T. Kumano, T. Haratani, N. Fujii, ISIJ Int, 45 (2005) 95-100.

Google Scholar