薄带连铸取向硅钢极薄带的二次再结晶行为

电工钢 ›› 2024, Vol. 6 ›› Issue (6): 1-.

薄带连铸取向硅钢极薄带的二次再结晶行为

取向硅钢极薄带因超低铁损、高磁感的优良性能成为电力、电子、军事等领域的关键材料。薄带连铸技术的亚快速凝固特性可以使取向硅钢在加工过程中产生高密度抑制剂粒子，解决传统生产流程条件下，极薄带的抑制剂粒子快速粗化导致对基体晶粒的钉扎力减弱、形成不完善二次再结晶组织的问题。高能（HE）晶界对Goss晶粒异常长大有重要作用。在925~950 ℃高温退火过程中，极薄带的晶粒尺寸变化不大，Goss晶粒周围的HE晶界比例提高；950 ℃以后，Goss晶粒周围的晶界率先移动，吞并基体晶粒发生异常长大，且其周围的HE晶界比例不断降低，直至1 000 ℃完成二次再结晶。

（东北大学轧制技术及连轧自动化国家重点实验室，辽宁沈阳 110819）

出版日期:2024-12-28 发布日期:2025-01-02

Secondary recrystallization behavior in ultra-thin grain-oriented silicon steel produced by strip casting

Ultra-thin grain-oriented silicon steel strip is a key material applying on these fields, such as power, electronics, and military, because of its ultralow iron loss and high magnetic induction. Sub-rapid solidification characteristic of the strip casting technology contributes to produce highdensity inhibitor particles during processing of grain-oriented silicon steel. It helps to solve the problem that the rapid coarsening of inhibitor particles in ultra-thin strip leads to the weakened pinning force exerting on matrix grains, which results in incomplete secondary recrystallization structure. High-energy (HE) grain boundaries play an important role in the abnormal growth of Goss grains. During high-temperature annealing process at 925~950 ℃, the change of grain size of ultra-thin strip is not significant, and the proportions of HE grain boundaries around Goss grains increase. When the temperature is above 950 ℃, the grain boundaries around Goss grains move firstly, thus Goss grains swallow up the matrix grains to form abnormally grown grains. During abnormal growth stage, the proportion of HE grain boundaries surrounding Goss grains decrease continuously until secondary recrystallization is completed at 1 000 ℃.

(State Key Laboratory of Rolling and Automation, Northeastern University, Shenyang 110819, China)

Online:2024-12-28 Published:2025-01-02

摘要/Abstract

摘要： 取向硅钢极薄带因超低铁损、高磁感的优良性能成为电力、电子、军事等领域的关键材料。薄带连铸技术的亚快速凝固特性可以使取向硅钢在加工过程中产生高密度抑制剂粒子，解决传统生产流程条件下，极薄带的抑制剂粒子快速粗化导致对基体晶粒的钉扎力减弱、形成不完善二次再结晶组织的问题。高能（HE）晶界对Goss晶粒异常长大有重要作用。在925~950 ℃高温退火过程中，极薄带的晶粒尺寸变化不大，Goss晶粒周围的HE晶界比例提高；950 ℃以后，Goss晶粒周围的晶界率先移动，吞并基体晶粒发生异常长大，且其周围的HE晶界比例不断降低，直至1 000 ℃完成二次再结晶。

关键词: 薄带连铸, 取向硅钢, 极薄带, 二次再结晶, Goss

Abstract: Ultra-thin grain-oriented silicon steel strip is a key material applying on these fields, such as power, electronics, and military, because of its ultralow iron loss and high magnetic induction. Sub-rapid solidification characteristic of the strip casting technology contributes to produce highdensity inhibitor particles during processing of grain-oriented silicon steel. It helps to solve the problem that the rapid coarsening of inhibitor particles in ultra-thin strip leads to the weakened pinning force exerting on matrix grains, which results in incomplete secondary recrystallization structure. High-energy (HE) grain boundaries play an important role in the abnormal growth of Goss grains. During high-temperature annealing process at 925~950 ℃, the change of grain size of ultra-thin strip is not significant, and the proportions of HE grain boundaries around Goss grains increase. When the temperature is above 950 ℃, the grain boundaries around Goss grains move firstly, thus Goss grains swallow up the matrix grains to form abnormally grown grains. During abnormal growth stage, the proportion of HE grain boundaries surrounding Goss grains decrease continuously until secondary recrystallization is completed at 1 000 ℃.

Key words: Strip casting, Grainoriented silicon steel, Ultrathin strip, Secondary recrystallization, Goss

王银平, 宋红宇, 王佳夫, 王国栋, 刘海涛. 薄带连铸取向硅钢极薄带的二次再结晶行为[J]. 电工钢, 2024, 6(6): 1-.

WANG Yinping, SONG Hongyu, WANG Jiafu, WANG Guodong, LIU Haitao. Secondary recrystallization behavior in ultra-thin grain-oriented silicon steel produced by strip casting[J]. Electrical Steel, 2024, 6(6): 1-.

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