{411}<148> Texture in Thin-Gauge Grain-Oriented Silicon Steel

doi:10.1007/s40195-016-0419-9

Abstract

Abstract:

The significant occupancy of {411}<148> texture exists in the thin-gauge grain-oriented silicon steel (TG-CRGO is defined that thickness of the sheet is <0.25 mm and the reduction in cold rolling is more than 90%) which has been considered to have obviously effects on the abnormal growth of Goss-oriented grains during the secondary recrystallization process. The microstructures of the TG-CRGO were investigated by X-ray diffraction and electron back-scattered diffraction in this study. It was found that {411}<148> texture mainly exists in the center layer of hot-rolled as well as normalized plates. With the increase in cold rolling reduction, {411}<148> orientation gradually rotates to α-fiber texture (<110>//RD). Finally, few {411}<148> would retain at the boundaries of deformed α-fiber grains (<110>//RD) as the reduction in cold rolling reaches 90%. After annealing treatment, a small amount of γ-fiber textures (<111>//ND) preferably nucleates and recrystallizes between the DBs (deformation bands) at first; then, the {411}<148> recrystallization texture occurs and mainly nucleates at the grains boundaries of the deformed α-fiber grains, and also quite a few {411}<148> orientation grains nucleate in the inner of {112}<110> grains. But this phenomenon was not observed in the {100}<011> deformation grains. With respect to the occurrence of {411}<148> recrystallization texture, it is mainly induced by strong α-fiber as well as weak γ-fiber textures formed during cold rolling other than originating from {411}<148> regions in hot bands.

Key words: Thin-gauge grain-oriented silicon steel (TG-CRGO), {411}<148> texture, α-Fiber texture, Recrystallization, Electron back-scattered diffraction (EBSD)

Cheng-Xu He, Fu-Yao Yang, Guang Ma, Xin Chen, Li Meng. {411}<148> Texture in Thin-Gauge Grain-Oriented Silicon Steel[J]. Acta Metallurgica Sinica (English Letters), 2016, 29(6): 554-560.

Figures/Tables 8

Fig. 1 EBSD orientation images of the specimens: a hot-rolled plate, b normalized plate, c cold rolling plate with 60% reduction, d cold rolling plate with 90% reduction

Fig. 2 Proportions of different oriented grains in hot-rolled plate

Fig. 3 EBSD orientation images of the specimens after different annealing time: a 15 s, b 20 s, c 25 s, d 30 s, e 35 s, f 40 s

Fig. 4 EBSD orientation image and {200} pole figure of the cold-rolled specimens with reduction of 50%: a orientation distribution map, b {200} pole figure

Fig. 5 EBSD orientation image of {112}<110> grain interior during cold rolling: a orientation distribution map, b {200} pole figure

Fig. 6 Observation of partially recrystallized texture: a early stage of recrystallization, b ODF of deformation band (φ2 = 45°), c ODF of recrystallization texture (φ2 = 45°), d ODF of deformation band (φ2 = 45°), e late stage of recrystallization

Fig. 7 Macro-textures of recrystallized specimens in different areas: a surface, b subsurface, c center

Fig. 8 Macro-textures of cold-rolled specimens in different areas: a surface, b subsurface, c center

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