Microstructure ＆ texture evolution and magnetic properties of high magnetic-induction 6.5% Si electrical steel thin sheet fabricated by a specially designed rolling route

Electrical steel sheets with 6.5%(mas fraction) Si with good shapes and superior magnetic inductions were successfully produced by a specially designed processing route including ingot casting, hot rolling and warm rolling both with interpass thermal treatment, and final annealing. The sheets were of 0.2 mm and 0.3 mm thick over 140 mm width. A detailed study of the microstructural and textural evolutions from the hot rolling to annealing was carried out by optical microscopy, X-ray diffraction and electron backscattered diffraction. The hot rolled sheet characterized by near-equiaxed grains was dominated by the mixture of <001>//ND fiber(λ-fiber), <110>//RD fiber(α-fiber) and <111>//ND fiber(γ-fiber) textures owing to the partial recrystallization and strain induced boundary migration(SIBM) during the hot rolling interpass thermal treatment. The static recovery and SIBM during the warm rolling interpass thermal treatment result in large and elongated warm rolling grains. The warm rolling texture is dominated by obvious λ, Goss and strong γ-fiber textures. The application of the interpass thermal treatment during hot and warm rolling significantly enhances the impact of SIBM during annealing, which is responsible for the formation of the moderate λ-fiber, some near-λ fiber texture components and the obviously weakened γ-fiber texture in the annealed sheet, leading to a higher magnetic induction compared to the commercially produced 6.5% Si steel by chemical vapor deposition(CVD).

6.5% Si电工钢的特性及应用

介绍高硅(6.5%Si)电工钢的特性及生产方式,同时叙述了该牌号电工钢国内外的发展及应用情况.高硅电工钢的研制和开发具有重要的现实意义.

6.5%Si电工钢复合板的制备与性能

以普通硅钢和硅铁合金为原料,采用包覆浇铸法制备具有三层结构的高硅电工钢铸坯,之后结合传统的轧制工艺和扩散退火工艺获得了6.5%Si电工钢复合板,利用光学显微镜和扫描电镜研究了其显微组织和硅元素的分布,并对其磁性能进行了测试。结果表明:采用上述工艺方法成功制备出了0.5mm厚的电工钢复合板;经1 200℃×75min扩散退火后,电工钢复合板中的硅元素发生了完全扩散,复合板由三层结构变成单层结构,整体硅元素质量分数约为6.5%;6.5%Si电工钢复合板的铁损P1.5/50为2.68~2.72 W·kg-1,磁感应强度B8为1.370~1.378T、B50为1.610~1.625T;与0.34mm厚的Fe-6.5%Si合金相比,复合技术制备的6.5%Si电工钢复合板的磁感应强度较高,但铁损也略高。

钇元素对6.5%Si无取向硅钢组织、高温拉伸及断裂机制的影响

通过微观组织表征、高温拉伸和断口形貌分析,研究了钇(Y)元素对6.5%Si无取向硅钢组织、高温拉伸及断裂机制的影响。研究结果表明,添加Y元素可以在钢液中形成YS和YP的复合析出。YS和YP可以充当异质形核基底,提高形核率,细化凝固组织。热轧组织不均匀,由表层至芯部分别形成等轴晶、等轴晶/拉长晶和拉长晶的混合组织。退火后,热轧变形组织转变为等轴晶,含Y实验钢的退火组织得到明显细化。500℃时效处理后,含Y实验钢具备较低的有序度,300℃的拉伸断口呈现韧性断裂特征,断后伸长率达到20.2%。相反,无Y实验钢发生脆性断裂,断后伸长率仅为2.1%。研究结果证实,Y元素可以通过组织细化和降低有序度提高6.5%Si无取向硅钢的中温塑性。

稀土Ce对薄带连铸无取向6.5%Si钢组织、高温拉伸性能和断裂模式的影响

研究了Ce元素对薄带连铸无取向6.5%Si钢凝固组织、有序相、高温拉伸性能和断裂模式的影响。结果表明,添加Ce可以在薄带连铸过程中形成高熔点Ce_(2)O_(2.5)S和Ce_(2)O_(2.5)S_(3),促进钢液异质形核,细化铸带凝固组织。Ce对有序相变无明显影响,铸带有序度由高至低所对应的拉伸温度分别为650、400和800℃。随拉伸温度提高,铸带的屈服强度与抗拉强度降低,断后延伸率提高。当拉伸温度高于500℃,Ce元素的钢液净化和凝固组织细化作用有助于提高晶界强度,避免沿晶断裂。铸带在拉伸过程中发生动态回复和再结晶,最终发生韧性断裂,断后延伸率得到显著提高。研究结果证实,稀土处理可以作为薄带连铸无取向6.5%Si钢增塑的一种有效途径。

Y对无取向6.5%Si钢凝固组织、中温压缩变形和软化机制的影响

利用EPMA、EBSD、XRD、TEM和热压缩测试,研究了Y元素对无取向6.5%Si钢铸态组织、有序相、中温变形和软化机制的影响。结果表明,当Y含量为0.017%和0.15%时,钢液中形成高熔点Y_(2)O_(3)+Y_(2)O_(2)S/Y_(2)O_(2)S-YP复合稀土化合物,促进异质形核。凝固末期,枝晶间形成Y_(2)Fe_(14)Si_(3)化合物,凝固组织得到明显细化。铸锭的基体有序度与Y含量呈反比关系。500℃压缩实验结果表明,不同Y含量铸锭的塑性变形均由位错滑移机制主导。含Y试样峰值应力对应的临界应变降低,加工软化提前,加工硬化率下降,动态软化作用增强。热压缩试样的位错密度正比于Y含量,低基体有序度和高形变诱导无序作用是含Y试样动态软化作用增强的主要原因。