Secondary Recrystallization Behaviors of Grain-Oriented 6.5 wt% Silicon Steel Sheets Produced by Rolling and Nitriding Processes

doi:10.1007/s40195-016-0390-5

Abstract

Abstract:

By rolling and nitriding processes, 0.23- to 0.3-mm-thick grain-oriented 6.5 wt% silicon steel sheets were produced. The core losses of grain-oriented 6.5 wt% silicon steel at frequencies ranging from 400 Hz to 20 kHz were lower than that of the grain-oriented 3 wt% silicon steel with the same thickness by 16.6-35.8%. The secondary recrystallization behavior was investigated by scanning electron microscopy, energy-dispersive spectroscopy, and electron backscattered diffraction. The results show that the secondary recrystallization in high-silicon steel sheets develops more completely as the nitrogen content increases after nitriding, secondary recrystallized grain sizes become larger, and the sharpness of Goss texture increases. Because more {110}?116?{110}?116? grains in the subsurface and the central layer of the sheets have a lot of 20°-45° high-energy boundaries in addition to Goss grains, {110}?116?{110}?116? can be the main component through selective growth during secondary recrystallization when the inhibitor quantity is not enough and inhibitor intensity is weaker. The increases in nitrogen content can increase the inhibitor intensity and hinder abnormal growth of a mount of {110}?116?{110}?116? grains and therefore enhance the sharpness of Goss texture.

Key words: Grain-oriented, 6.5, wt%, silicon, steel, Secondary, recrystallization, Rolling, Nitriding, Inhibitor

Jing Qin, Ping Yang, Wei-Min Mao, Feng Ye, Li Liu. Secondary Recrystallization Behaviors of Grain-Oriented 6.5 wt% Silicon Steel Sheets Produced by Rolling and Nitriding Processes[J]. Acta Metallurgica Sinica (English Letters), 2016, 29(4): 344-352.

Figures/Tables 8

Fig. 1 Macrostructures, {200} pole figures (levels: 1, 2, 4, 6, 8), and ODFs (φ 2 = 45°, levels: 1, 2, 4, 6, 8, 10, 12, 16, 20, 25) of 0.3-mm-thick grain-oriented 6.5 wt% silicon steel sheets and the nitriding time of 30 s a, 60 sb, 90 s c

Table 1 Magnetic properties of grain-oriented 6.5 wt% silicon steel sheets at 50 Hz

Thickness (mm)	Nitriding time (s)	Magnetic flux density (T)		Core loss (W/kg)
Thickness (mm)	Nitriding time (s)	B ₈	B ₅₀	P_1.0/50	P _1.5/50
0.3	30	1.525	1.761	0.585	1.567
	60	1.537	1.762	0.581	1.568
	90	1.555	1.775	0.603	1.502
0.23	90	1.570	1.797	0.378	1.135

Fig. 2 Comparison of core losses between 3 and 6.5% grain-oriented silicon steels

Fig. 3 Orientation images and ODFs (φ 2 = 0°, 45°; levels: 1, 2, 3, 4, 5) of the samples, which are nitrided for 30 sa, 60 s b, and 90 s c and their area fractions of main texture components d

Fig. 4 Local orientation images, {200} pole figures, and ODFs (levels: 1, 2, 4, 8, 10, 20, 40, 80) of the samples, which are nitrided for 60 s and extracted at 850 °C a, 875 °C b, 900 °C c, 925 °C d, 950 °C e, 975 °C f, 1000 °C, g 1050 °C h, and 1075 °C i during the secondary recrystallization annealing

Table 2 Area fractions of main texture components in Fig. 4 (%)

Temperature (°C)	{112}?110?	{112}?241?	{111}?110?	{111}?112?	{210}?001?	{100}?011?	{100}?001?	{110}?116?	{110}?001?
850	0.5	25.8	0.2	6.8	7.0	2.3	6.5	5.5	3.5
875	4.0	12.0	1.0	5.2	16.9	2.5	6.5	6.5	2.2
900	3.5	16.5	2.5	6.0	7.7	0.2	5.4	5.0	4.3
925	5.3	15.2	3.7	4.1	9.2	1.0	4.4	17	4.2
950	0	0	0	0	32.3	0	0	53.1	0

Fig. 5 Distribution a, micrograph b, and EDS analysis c of the precipitates after nitriding for 60 s

Fig. 6 Distribution of the precipitates at 875 °C a, 900 °C b, and 925 °C c in the surface and the central layer of samples nitrided 60 s and EDS analysis of the precipitates d

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