Effect of decarburization annealing temperature and time on the carbon content, microstructure, and texture of grain-oriented pure iron

Hai-jun Wang; Zhe Rong; Li Xiang; Sheng-tao Qiu; Jian-xin Li; Ting-liang Dong

doi:10.1007/s12613-017-1419-0

International Journal of Minerals, Metallurgy, and Materials ›› 2017, Vol. 24 ›› Issue (4) : 393 -400. DOI: 10.1007/s12613-017-1419-0

Article

Effect of decarburization annealing temperature and time on the carbon content, microstructure, and texture of grain-oriented pure iron

Author information +

History +

PDF

Abstract

In this study, the effect of decarburization annealing temperature and time on the carbon content, microstructure, and texture of grain-oriented pure iron was investigated by optical microscopy and scanning electron microscopy with electron-backscatter diffraction. The results showed that the efficiency of decarburization dramatically increased with increasing decarburization temperature. However, when the annealing temperature was increased to 825°C and 850°C, the steel’s carbon content remained essentially unchanged at 0.002%. With increasing decarburization time, the steel’s carbon content generally decreased. When both the decarburization temperature and time were increased further, the average grain size dramatically increased and the number of fine grains decreased; meanwhile, some relatively larger grains developed. The main texture types of the decarburized sheets were approximately the same: {001}<110> and {112~115}<110>, with a γ-fiber texture. Furthermore, little change was observed in the texture. Compared with the experimental sheets, the texture of the cold-rolled sheet was very scattered. The best average magnetic induction (B ₈₀₀) among the final products was 1.946 T.

Keywords

pure iron / decarburization / annealing temperature / annealing time / carbon content / microstructure / texture

Cite this article

Download citation ▾

Hai-jun Wang, Zhe Rong, Li Xiang, Sheng-tao Qiu, Jian-xin Li, Ting-liang Dong. Effect of decarburization annealing temperature and time on the carbon content, microstructure, and texture of grain-oriented pure iron. International Journal of Minerals, Metallurgy, and Materials, 2017, 24(4): 393-400 DOI:10.1007/s12613-017-1419-0

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	He Z.Z., Zhao Y., Luo H.W. Electrical Steel, 2012, Beijing, Metallurgical Industry Press, 646.

[2]	Blaugher R.D., Hopkins R.H. Development of Grain-oriented Iron Sheet for Electrical Apparatus, 1981

[3]	Thornburg D.R. Method of Producing Primary Recrystallized Textured Iron Alloy Member Having an Open Gamma Loop, 1975

[4]	Wada T., Takashima K., Kawashima M. (110)[001] Textured 0.80% Si−Fe for the proton synchrotron. AIP Conf. Proc., 1974, 18(1): 1363.

[5]	Hiroyoshi Y., Masashi T. Manufacture of Grain Oriented Electrical Steel Sheet, 1986

[6]	Hiroyoshi Y., Atsuki O. Production of Grain Oriented Electrical Steel Sheet, 1987

[7]	Hiroyoshi Y., Teruo K. Production of Grain-oriented Magnetic Steel Sheet, 1989

[8]	Hiroyoshi Y., Teruo K. Grain-oriented Magnetic Steel Sheet and Its Production, 1989

[9]	Yoshio N., Yasuo O. Production of Unidirectionally Oriented Electrical Steel Sheet Having High Magnetic Flux Density, 1991

[10]	Ujihiro N., Tsutomu K., Kiyohiko N., Kazuhiro S. Soft Magnetic Iron Sheet Excellent in Magnetic Property and Its Manufacture, 1992

[11]	Yoshio N., Yasuo O. Production of Grain-oriented Electrical Steel Sheet Having High Magnetic Flux Density, 1992

[12]	Yoshio N., Yasuo O. Grain-Oriented Pure Iron Excellent in Magnetic Permeability and Coercive Force in Coil-width Direction and Its Production, 1992

[13]	Yoshio N., Yasuo O., Tadao N., Takashi M., Takeo N., Shuichi Y., Hiroyasu F., Takao K. Grain-oriented Silicon Steel Sheet Having Excellent Magnetostrictive Characteristic, 1995

[14]	Ryutaro K., Takeaki W. Production of Grain-oriented Silicon Steel Sheet Extremely High in Magnetic Flux Density, 1998

[15]	Ryutaro K., Takeaki W. Manufacture of Grain Oriented Silicon Steel Sheet Having Stable and Extremely High Magnetic Flux Density in Longitudinal Direction of Coil, 1998

[16]	Ryutaro K., Takeaki W. Manufacture of Grain Oriented Silicon Steel Sheet Having Extremely High Magnetic Flux Density, 1998

[17]	Ryutaro K., Takeaki W. Production of Grain Oriented Silicon Steel Sheet with Extremely High Magnetic Flux Density, 1999

[18]	Takeaki W., Ryutaro K. Grain Oriented Silicon Steel Sheet with Extremely High Magnetic Flux Density, and Its Manufacture, 1999

[19]	Fu B., Wang H.J., Yan J.X., Xiang L., Qiu S.T., Cheng G.G. Effects of temperature and alloying elements on γ phase fraction of grain-oriented silicon steel. J. Iron Steel Res. Int., 2016, 23(6): 573.

[20]	Takahashi N., Suga Y., Kobayashi H. Recent developments in grain-oriented silicon-steel. J. Magn. Magn. Mater., 1996, 160(7): 98.

[21]	Wriedt H.A. Solubility product of aluminum nitride in 3 percent silicon iron. Metall. Trans. A, 1980, 11(10): 1731.

[22]	Luo H.W., Xiang R., Chen L.F., Pan L.M. Modeling decarburization kinetics of grain-oriented silicon steel. Chin. Sci. Bull., 2014, 59(15): 1778.

[23]	Dai L.Z. The recrystallization and magnetic properties of Armco iron. Acta Metall. Sin., 1958, 3(3): 227.

[24]	Dai L.Z., Zhang X.Y. The rolling and recrystallization textures of Armco iron. Acta Phys. Sin., 1958, 14(1): 17.

[25]	Li C.Y., Fang Z.M., Liang L.Z., Quan S.J. Theoretical and experimental study on surface decarburization of ₆₀Si2Mn spring steel. Trans. Mater. Heat Treat., 2015, 36(1): 192.

[26]	Marques M.K., Azevedo A.E.D., Lopes B.V.T. Decarburization kinetics during annealing of a semi-processed electrical steel. ISIJ Int., 2004, 44(3): 618.

[27]	Park J.Y., Han K.S., Woo J.S., Chang S.K., Rajmohan N., Szpunar J.A. Influence of primary annealing condition on texture development in grain oriented electrical steels. Acta Mater., 2002, 50(7): 1825.