薄板坯连铸连轧工艺下Hi-B钢的组织及织构

采用金相显微镜和扫描电镜研究实验室模拟薄板坯连铸连轧（TSCR）工艺试制的高磁感取向硅钢（Hi-B钢）组织、织构的演变特征.研究发现实验室模拟薄板坯连铸连轧工艺试制的Hi-B钢热轧板显微组织及织构在厚度方向上存在不均匀性.常化板表面脱碳层铁素体晶粒明显粗化,常化板织构基本继承了热轧板相应的织构类型,仅织构强度不同.一次大压下率冷轧后,晶粒及其晶界沿轧向被拉长形成鲜明的纤维组织,织构主要为α纤维织构和γ纤维织构,脱碳退火后试样发生回复和再结晶现象并形成初次晶粒组织,脱碳退火后织构分布较为集中.温度升高至1000℃时二次再结晶开始,1010℃时钢中晶粒发生异常长大,高斯织构强度达到61.779.成品磁感为1.915 T,铁损为1.067 W·kg-1.      

普通晶粒取向电工钢高温退火前的显微组织对二次再结晶的影响

研究了普通晶粒取向电工钢高温退火前的显微组织对二次再结晶的影响。在高温退火前 ,冷轧试样在 6 0 0～ 85 0℃ ,2 5 %H2 +75 % N2 气氛下退火 2 0 0 s,目的是获得回复和再结晶组织。为观察晶粒尺寸和沉淀析出物 ,在高温退火期间 ,分别在 70 0、80 0、90 0、95 0和 10 0 0℃提取试样。对于高温退火前再结晶的试样 ,经 95 0℃高温退火后其二次再结晶几乎已经完成。然而 ,在回复试样中 ,高于 95 0℃温度才出现二次再结晶。高温退火后 ,回复试样的磁性比再结晶试样好普通晶粒取向电工钢高温退火前的显微组织对二次再结晶的影响@茅益明…     

高温渗氮Hi-B钢二次再结晶中组织及织构演变

模拟CSP工艺试制Hi-B钢在二次再结晶过程中不同退火温度下的组织和织构。使用Zeiss Axioplan金相显微镜(OM)观察试样组织,借助于NOVA400Nano SEM型场发射扫描电子显微镜进行微观织构EBSD检测分析。结果表明:Goss晶粒在1 040℃发生异常长大,异常长大之前晶粒细小均匀,有利的{111}〈112〉和{411}〈148〉织构为主要织构,异常长大后部分晶粒发生快速长大,组织则以Goss织构为主。Goss织构及{111}〈112〉和{411}〈148〉织构的取向差分布主要集中在20°~45°之间,高能晶界理论(HE)能够解释Goss晶粒的异常长大。基体的CSL晶界比例较低,且移动性差的∑3晶界比例较高,移动性好的∑5、∑7、∑9晶界比例较低,CSL晶界理论对于Goss晶粒的异常长大则不具有说服力。     

热轧板常化工艺对取向硅钢冷轧板退火组织和性能的影响

试验研究了取向硅钢(/%:0.046C,3.07Si,0.09Mn,0.029P,0.004S,0.005 Al,0.001Ti,0.001 40,0.009 6N)2.66 mm热轧板1 100℃2 min空冷10 s至960℃3min空冷常化后,经一次冷轧,中间退火,二次冷轧0.3 mm板,820℃5 min空冷初次再结晶退火,并经1 050℃空冷二次再结晶退火后的组织、织构和磁性能。通过对比常化和无常化样品的初次再结晶退火后试样以及二次再结晶退火后试样的组织和性能,得出常化工艺对退火过程的影响。结果表明,热轧板常化处理可以降低冷轧板初次退火后的初次再结晶晶粒尺寸,使∑₉晶界和大角度晶界百分含量增加,高斯取向晶粒含量增加,还可以使二次再结晶晶粒增大,提高磁感应强度、降低铁损。     

中温含铜取向硅钢的形变和再结晶织构特征

通过对比中温含铜取向硅钢与普通取向硅钢和高磁感取向硅钢的组织和织构特征,分析中温含铜取向硅钢独特的织构演变规律及其对二次再结晶行为的影响.结果表明,为了获得有利于高斯晶粒长大的强γ取向线织构,中温含铜钢需经过回复退火处理和高温退火阶段慢速升温.回复过程中γ取向线晶粒储能降低,同时慢速升温有利于γ取向线晶粒的形核和再结晶.中温含铜钢的二次再结晶开始温度超过1000℃,由于初次再结晶晶粒组织以γ织构为主且非γ取向线晶粒较少,导致最终二次晶粒尺寸超大且晶界圆滑,二次再结晶机理以择优长大为主导,超大的二次晶粒尺寸导致最终成品的铁损升高,但通过激光刻痕处理后,整体铁损的降低效果比二次晶粒较小的高磁感取向硅钢更加显著.      

在动态热处理条件下对取向电工钢二次再结晶的研究

对应用动态加热进行短时温度退火的取向电工钢进行了二次再结晶研究。所进行研究的实验用取向电工钢是经过终冷轧和后续罩式退火后的一条工业化生产线生产的。研究结果表明,运用短时热处理条件可引起研究钢完全的异常晶粒长大。在实验室处理的材料的织构和金相组织与工业化生产的经过终退火而获得的相同的取向电工钢类似。但是,在实验室处理的取向电工钢的二次再结晶的矩阵中可观测到"寄生"晶粒。从磁性观点看,这些"寄生"晶粒含有不理想的{111}取向织构。     

铁硅合金中形成立方织构的有关问题

评述了铁硅合金中通过二次再结晶获得立方织构的一些基本规律。从变形与再结晶织构形成的机理 ,讨论了二次再结晶时立方“晶核”的获得 ,以及 (hk0 ) [0 0 1 ]初次再结晶织构的获得 ;当杂质偏聚或第二相沉积在晶界上后 ,由于不同取向晶粒间构成的晶界特性不同 ,对晶界迁移速率的影响会有很大的差别 ,讨论了获得取向合适的初次再结晶织构的重要性 ;从杂质原子在表面吸附后会降低 ( 1 0 0 )晶面的表面能 ,促使立方晶粒在最后退火时长大 ,讨论了退火气氛的重要性。根据这些原则 ,可以指导如何确定冷轧次数、冷轧变形量、中间退火温度以及最后退火温度和气氛 ,以便获得更集中的立方织构。     

Fe-6.5%Si合金温轧后退火过程中再结晶行为

用电子背散射技术观察了700℃温轧板在退火过程中的组织及织构演变以了解其再结晶行为.结果表明,温轧织构由强的（111）〈112〉、较弱的〈110〉∥RD及Goss组成,再结晶织构与之相似.〈110〉∥RD及（111）〈112〉新晶粒首先形成于与之构成小角度晶界的形变晶粒的晶界附近,而在角隅及组织不均匀区等位置孕育出与周围晶粒构成大角度晶界的晶核,择优取向不明显.退火过程中（111）〈112〉在形变组织中累积,最终转化为（111）〈112〉再结晶晶粒.分析认为,温轧后退火是不均匀组织在低储存能驱动下的再结晶过程.（112）〈110〉及（111）〈112〉形变拉长晶粒多发生连续再结晶从而退火织构与形变态相似.在角隅区形成核心进而发生不连续再结晶,核心取向的统计性及不连续晶核的长大弱化再结晶织构,其中Goss晶粒多以此方式形成于（111）〈112〉晶粒内部.      

两次冷轧法轧制的无取向硅钢{001}〈210〉织构的发展

在元取向硅钢中，{001}〈210〉织构具有良好的磁性，而采用两次冷轧法（中间退火温度为640℃）能够坩强这种织构。利用电子背散射图形（EBSP），测量退火过程中亚擞织构的变化来研究两次冷轧法生产的无取向电工钢{001}〈210〉奴构的形成机理。中间退火钢板的再结晶份数为60％，主要由〈111〉／／ND小等轴再结晶晶粒和〈110〉／／RD伸长变形晶粒组成．在最终退火期间，再结晶晶粒〈111〉／／ND方向的长大被抑制。晶粒在{001}晶面〈210〉晶向上的长大使〈111〉／／ND方向的再结晶晶粒被消耗。这是由于再结晶晶粒中第二次冷轧在〈111〉／／ND方向引入的应变所造成的。所以，最终退火钢板的结构主要为{001}〈210〉织构。     

Bi对低温取向硅钢高温退火过程组织和织构的影响

以含Bi和不含Bi两种成分低温取向硅钢进行高温退火中断实验，借助磁测仪（MPG 200D）进行磁性能测量，借助金相显微镜观察晶粒尺寸，利用X射线衍射（XRD）对高温退火连续升温过程中织构进行研究分析。实验结果表明，添加Bi元素后，初次晶粒尺寸减小，二次再结晶晶粒尺寸增加至20~60 mm，成品磁性能更优。Bi加入后二次再结晶开始温度明显提高，含Bi试样和不含Bi试样发生晶粒异常长大的温度范围分别是1 080~1 100 ℃和1 060~1 080 ℃。织构分析结果显示，随着高温退火温度提高，{111}和{100}面织构逐渐减弱，{110}面织构和Goss织构逐渐增强，含Bi和不含Bi试样的高斯织构转变温度分别为1 100 ℃和1 080 ℃，随后高斯织构密度和体积百分比逐步增加，最终含Bi试样的高斯织构密度和体积百分比均高于不含Bi试样。     

铌对低温取向硅钢初次再结晶行为的影响

以含铌取向硅钢铸坯低温加热制备高磁感取向硅钢为研究目标,通过研究铌对低温取向硅钢初次再结晶行为的影响,达到获得有利于二次再结晶发展的初次再结晶组织目的,采用OM和EBSD技术主要对比了 0.055％铌和不含铌对低温取向硅钢中间退火板的初次再结晶组织、织构和晶界特征的影响.结果表明,铌的加入,使硅钢基体中形成了细小弥散的...     

卷取温度对高强IF钢再结晶及织构的影响

为了研究卷取温度对高强IF钢250P1罩式退火再结晶规律的影响,采用氮气炉加热模拟罩式退火工艺,研究了高温及低温卷取工艺下含磷高强IF钢250P1冷轧板再结晶规律;采用X射线衍射仪对700 ℃模拟退火板及罩式退火成品板进行了织构分析,并对成品板金相组织进行了观察。结果表明,低温卷取冷轧板再结晶温度约为675 ℃,高温卷取冷轧板再结晶温度约为700 ℃;低温卷取退火板具有较高强度的{111}有利织构、较高的{111}/{100}比值以及r值,成品板的饼形晶粒更大。     

Effect of Heating Rate on Microstructure Evolution and Magnetic Properties of Cold Rolled Non-Oriented Electrical Steel

The effects of heating rate (ranging from 50 to 300 ℃/s) during the final annealing process on microstructure evolution and magnetic properties of cold rolled non-oriented electrical steel were investigated. It was found that increasing heating rate increased the nucleation temperature and complete recrystallization temperature. At the same time, heating rate increasing could cause the substantially refined structures for the recrystallization grains and this grain refinement would decline when the heating rate was beyond 50 ℃/s. The recrystallization texture exhibited pronounced improvement with heating rate, such as the intensity decrease of 111ND (normal direction) fiber and the intensity increase of {110}001 Goss texture component. The texture improvement and grain size refinement caused by heating rate increasing resulted in complicated variation of the magnetic properties. The magnetic induction (B50) keeps increasing while heating rate increases from 15 to 300 ℃/s which is due to the recrystallized texture optimization caused by rapid heating. The core losses (P1.5/50) decrease while heating rate increases from 15 to 100 ℃/s; however, the core losses would increase when heating rate is higher than 100 ℃/s, which is caused by the mean grain size refinement after rapid heating annealing. The results indicate that recrystallization texture and the magnetic properties of the non-oriented electrical steel can be improved definitely by rapid heating during the final annealing treatment.     

退火温度对超薄取向硅钢织构及磁性能的影响

 为了研究中/高频用超薄取向硅钢制备工艺中退火温度对组织、织构及磁性能的影响,以商用0.27 mm规格无底层取向硅钢成品板为原料采用初次再结晶法制备了0.08 mm厚的超薄取向硅钢。系统研究了800~1 000 ℃温度范围内退火对超薄取向硅钢退火组织、织构及磁性能的影响。结果表明,过渡带中的η取向({0kl}<100>)与相邻形变基体呈大角度取向差晶界,再结晶开始时,η取向组分优先在过渡带边界“弓出”形核;随着退火温度升高,再结晶平均晶粒尺寸增大,{114}<481>等非η取向晶粒尺寸优势愈发明显,η组分体积占比降低,晶粒尺寸均匀性变差;稍低温退火时超薄取向硅钢综合磁性能较好,退火温度为800 ℃时,磁感应强度B₈₀₀=1.82 T,铁损P_1.5/400=11.66 W/kg,获得本试验条件下最佳综合中频磁性能。     

Secondary recrystallisation behaviours of grain-orientated silicon steel produced by TSCR process

Grain-oriented electrical steel is mainly used as the core material in electrical transformers, and its magnetic properties are closely related to the sharpness of Goss texture formed by secondary recrystallisation during high-temperature annealing. However, the mechanisms of abnormal Goss grain growth are still disputed in the literature. In this paper, grain-oriented silicon steel strips with AlN as main inhibitor were produced by thin slab casting and rolling process, and the evolution of microstructure and texture during high-temperature annealing was investigated. Moreover, the mechanisms of secondary recrystallisation were further discussed. The results show that secondary recrystallisation is actually a multi-stage process, and different mechanisms are at work at different stages. Coincident site lattice grain boundaries play an important role at the early stage of secondary recrystallisation, however, the role of high-energy grain boundaries and solid-state wetting should be more important at the later stage of secondary recrystallisation.     

Static Recrystallization Kinetics and Crystallographic Texture of Nb-Stabilized Ferritic Stainless Steel Based on Orientation Imaging Microscopy

In the present study, Nb-stabilized ferritic stainless steel was prepared with annealing (430-A) and without annealing (430-NA) annealing, and the microstructure of the resulting samples was examined. The steel was then subjected to cold rolling and isothermal annealing in order to analyze its recrystallization kinetics and texture evolution. Microstructural characterization was performed by scanning and transmission electron microscopies. Recrystallization kinetics were evaluated by measuring the microhardness of the samples, and analyzing their kernel average misorientation and grain orientation spread via electron backscatter diffraction. The Avrami exponent data revealed that one-dimensional grain growth occurred owing to the migration of high-angle grain boundaries. The mean activation energies for recrystallization for 430-NA and 430-A was found to be 365 and 419 kJ mol⁻¹, respectively. The recrystallization texture was influenced by oriented nucleation and selected growth mechanisms, as well as by the Nb carbonitride distribution and grain boundary energy. The recrystallized and growing grains with the {554}〈225〉 orientation showed a dimensional advantage over the other recrystallized components. The coincident site lattice boundaries were attributed to the progression of recrystallization since the CSL numeric fraction increased as the temperature increased. The {554}〈225〉 component was associated with the ∑19a boundary, which exerted a significant control on the selective growth during the recrystallization.

     

高性能取向硅钢的工业化生产研究

采用光学显微镜、X射线衍射仪等分析了宁波钢铁有限公司生产的取向硅钢不同工序下的组织及织构演变规律.结果 表明:铸坯经过热轧后,沿着厚度方向组织不均匀;一次冷轧并经脱碳退火后,组织由条状纤维状变成等轴状的初次再结晶晶粒,初次再结晶平均晶粒尺寸为18.17 μm,织构主要以α织构和γ织构为主;在二次冷轧后,晶粒再次被压缩,转变为纤维状,织构主要为γ织构;经过高温退火后,发生二次再结晶,晶粒异常长大,晶粒尺寸达到厘米级,织构成分为单一且锋锐的Goss织构.