IF钢罩式退火过程中再结晶组织与织构的演变

研究了IF钢(/%:0.005C、0.02Si、0.16Mn、0.011P、0.004S、0.042Als、0.061Ti、0.003 1 N)0.8 mm冷轧板在500～800℃退火时的再结晶组织及织构,采用X射线衍射技术结合微观组织观察分析了IF钢罩式退火过程中{111}再结晶织构形成机制和显微组织演变规律。结果表明,随退火温度的升高,再结晶数量逐渐增多,640℃为实验钢实际再结晶温度,同时{111}再结晶织构强度亦逐渐增大,{111}取向的晶粒主要在再结晶过程中形成,并在{111}取向晶粒长大过程中,γ纤维织构之间也发生相互转化,主要由{111}〈112〉织构转变为{111}〈110〉织构。     

冷轧Ti-IF超深冲钢罩式退火机理及织构变化规律的研究

在480~750℃条件下,模拟罩式退火,利用光学显微镜、X射线衍射和金相显微硬度计研究了冷轧Ti-IF超深冲钢晶粒结构的变化,通过取向密度函数分析了再结晶过程织构演变规律。研究表明:冷轧Ti-IF超深冲钢的再结晶温度约为630℃,再结晶过程能够在660℃条件下2 h之内完成;冷轧后该钢主要有4种织构,分别是{001}〈110〉、{111}〈110〉、{111}〈112〉和{112}〈110〉;在退火再结晶过程中,{111}逐渐转变为γ-{111},当退火温度升至720℃时,{001}〈110〉和{112}〈110〉转变为纤维织构γ-{111},最终{111}〈110〉和{111}〈112〉成为主要织构类型。     

B对含P高强度无间隙原子钢{111}面织构的影响

借助光学显微镜(OM)、X射线衍射(XRD)技术及电子背散射衍射(EBSD)技术,分析了2种含P高强度无间隙原子(IF)钢的热轧组织和热轧、冷轧及退火织构,结果表明:不含B与含B的高强IF钢热轧后,均得到多边形铁素体,但不含B热轧板晶粒尺寸较大。2种钢热轧板织构均比较散漫,γ纤维织构强度较弱,而不含B的IF钢经过80%大变形量冷轧以后,获得强的γ纤维织构,{111}面织构的体积分数达到41.41%,而含B的IF钢冷轧后{111}面织构的体积分数为33.83%。含B的IF钢冷轧后{112}110织构组分的体积分数比不含B的IF钢要高。2种实验钢在810℃退火60~180s以后,{111}面织构强度进一步增强,不含B的IF钢退火120s后{111}面织构的体积分数最大达到72.8%,而含B的IF钢退火120s后{111}面织构的体积分数最大达到66.6%。     

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。     

退火条件对IF钢再结晶织构和深冲性能的影响

研究了退火条件对IF钢组织、织构和性能的影响。通过ODF分析揭示了再结晶后晶粒长大过程中, {111}取向晶粒靠消耗其它取向(主芰是{100}取向)晶粒而长大,故随晶粒长大有利加强织构组分,γ值明显提高。     

冷轧压下率对Hi-B高磁感取向硅钢初次再结晶织构的影响

模拟CSP Hi-B钢(/%:0.05C,0.20Mn,3.47Si,0.001 5S,0.007P,0.027Al,0.006 0N)窄带制造流程为25 kg真空感应炉熔炼-浇铸成40 mm×85 mm扁锭-热轧2.5 mm板-930℃常化处理-冷轧成0.6 mm(76%),0.4mm(84%),0.3 mm(88%)和0.2 mm(92%)薄板-830℃5 min初次再结晶退火。采用X-射线衍射测量技术(XRD)对初次再结品退火后的试样进行织构分析。结果表明,初次再结晶退火后,GOSS织构主要形成于次表层,有少量的GOSS织构存存于76%压下量的1/4层;随压下量的增加,α纤维织构中的{112}〈1 10〉和{001}〈110〉取向强度逐渐减弱,而γ纤维织构中的{111}〈112〉和{111}〈110〉取向强度先增强后减弱;在压下量为88%时,γ纤维织构强烈向{111}〈112〉取向集中,强度达到最大,最有利于GOSS织构的形成。     

Ti、Nb对超低碳Cr18铁素体不锈钢冷轧板再结晶织构的影响

研究了添加Ti、Nb对超低碳Cr18铁素体不锈钢冷轧板再结晶织构的影响。试验结果表明,Nb单稳定化和Ti、Nb双稳定化的冷轧板试样在850℃下,随退火保温时间的延长,{111}面织构取向密度增加,而Ti单稳定的冷轧板在退火2min时{111}面织构取向密度值达到最大,然后随保温时间延长{111}面织构密度下降。Ti、Nb双稳定化的冷轧板经退火360s后得到最大的{111}<112>织构取向密度强度,Nb单稳定化Cr18不锈钢冷轧板再结晶织构{111}取向密度低于其它两种钢。     

退火温度和时间对含磷高强IF钢组织性能的影响

以超低碳含磷高强IF钢为研究对象,在实验室条件下进行了冷轧及模拟退火试验。结果表明,随退火温度的升高及退火时间的延长,试验钢再结晶越完全,晶粒形状更趋近等轴晶;试验钢退火后具有较强的{111}110和{111}112织构;采用700~720℃退火4 h可使试验钢各项力学性能指标满足标准要求。     

冷轧压下率对无抑制剂取向硅钢初次再结晶退火的影响

对无抑制剂取向硅钢不同压下率下初次再结晶退火后的显微组织、宏观织构和微观织构进行了研究.结果表明,冷轧板织构主要为α取向线{001}＜110＞、{112}＜110＞和{111}＜110＞织构以及γ取向线{111}＜110＞织构.初次再结晶退火后,α取向线织构减弱,织构主要为γ取向线{111}＜112＞织构.随冷轧压下率的增加,冷轧和初次再结晶织构强度增加.当压下率为88％时,初次再结晶退火后 Goss 织构和{111}＜112＞织构强度最高,最有利于发生二次再结晶.EBSD 分析显示,Goss 取向晶粒大多与{111}＜112＞取向晶粒相邻.提高冷轧压下率,Goss取向晶粒和{111}＜112＞取向晶粒都增加,Goss 取向晶粒偏离理想取向角度减少.     

IF钢冷轧及再结晶初期微观组织的TEM研究

采用透射电子显微镜对不同压下量和再结晶初期的IF钢样品进行了研究.结果表明:无论是在较小形变量下还是在较大形变量下,形变不均匀性是普遍存在的;冷变形程度不同,织构组分不同,TEM形貌也不同;在再结晶的最初期,冷轧的形变组织演变为近乎等轴的亚晶,优先形成{111}《uvw》取向的晶核,晶核逐渐吞并周围的形变基体而长大,最终形成再结晶γ-纤维织构.     

Formation of Nuclei With {111}<110> and {111}<112> Orientations of IF Steel at Early Stage of Recrystallization Using EBSD Analysis

The excellent deep drawability of interstitial free steel (IF steel) is closely related to its texture formed during recrystallization. The nucleation process of cold rolled IF steel at the early stage of recrystallization was investigated by electron back scattered diffraction (EBSD). The characteristics of the microstructure after deformation and the orientation of nucleation were observed. The results show that the deformed microstructure with 80% reduction could be subdivided into two groups. These two types of microstructure were characterized by their orientation and internal local misorientations. The nuclei with γ-orientation preferred to form in deformed bands with γ-orientation and at the boundaries between deformed grains with different orientations. The recrystallized grains with {111}<110> orientation appeared firstly in deformed matrix with {111}<112> orientation and consumed the matrix with {111}<112> to grow up, while the recrystallized grains with {111}<112> orientation were observed secondly in deformed matrix with {111}<110> orientation and consumed matrix with {111}<110> to grow up.     

Microstructure and texture evolution during recrystallization of low-carbon steel sheets

Aluminum killed low-carbon steel sheets were cold rolled at different reduction ratios and annealed using different temperatures and holding time.The Vickers hardness was examined.The results show that when cold rolling reduction ratios increase from 40% to 81%,recrystallization temperatures decrease from 602°C to 572°C during 4hisochronal annealing,as well recrystallization holding time decreases from 117 min to 5min during isothermal annealing at 610°C.All recrystallization temperatures and holding time can be calculated using the annealing experiment results.Microstructure was examined through electron backscattered diffraction(EBSD).The results show that as rolling direction preferentially grows,equiaxed grains grow into cake-type during recrystallization.Cake-type grains are more beneficial to obtaining ideal111//ND(normal direcrtion)orientation texture.{111}orientation grains nucleate and grow up preferentially.Deformation grains of{111}110orientations grow into new recrystallization grains of{111}123and{111}112during recrystallization.Texture formation can be explained by directional nucleation.     

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.      

快速加热条件下BH钢再结晶规律

 通过Gleeble-3500热模拟试验机以及运用金相、显微硬度、EBSD技术等研究方法,研究了不同加热速率对BH钢再结晶退火组织和织构演变的影响。结果表明：再结晶温度随加热速率的提高而升高。加热速率的提高,缩短了BH钢完成再结晶所需时间。快速加热条件下,BH钢再结晶晶粒得到细化,再结晶织构组分强度降低。EBSD分析发现：提高加热速率,再结晶完成后,再结晶织构仍以有利于深冲性能的管状γ织构为主。再结晶结束后,升高温度和增加保温时间有助于{111}织构的发展。在780℃保温一定时间的条件下,低加热速率形成以{111}〈112〉组分为主的再结晶织构,而快加热速率下{111}〈110〉织构组分得到一定的发展,γ织构强度分布更加均匀,有利于BH钢的成型性能。     

Orientation imaging microscopy studies of recrystallization in interstitial-free steel

The origin of the γ fiber recrystallization texture in interstitial-free (IF) steel developed during continuous annealing has been investigated by scanning electron microscopy (SEM) and orientation imaging microscopy (OIM). Nucleation of {111} «uvw» oriented crystals occurs in deformation banded γ grains and therefore a comprehensive study of microstructure of cold-rolled IF steel in the sections perpendicular to the rolling and transverse directions (TDs) and the rolling plane (RP) has been carried out to understand the formation, geometry, and microstructural features of recrystallization. The RP section gave abundant evidence of orientation gradients formed in γ oriented grains that had been subject to orientation splitting to give deformation bands. These orientation gradients across a single grain are around 5 to 30 deg and this orientation difference is sufficient to form nuclei with mobile interfaces during annealing and hence to create chains of γ oriented new grains in the original hot band γ grain envelopes. A grain impingement model requiring orientation pinning is then proposed to explain how these grains, contained in deformed γ grain envelopes, grow out into their neighbors to dominate the final recrystallization texture of IF steel. The α deformed grains contain only small lattice curvatures, and therefore in-grain nucleation is rare. These grains are mostly consumed by invading γ grains toward the end of the recrystallization process.     

Determination of Optimal Recrystallization Annealing Temperature of Nb-Ti Microalloyed High Strength IF Steel

The Nb-Ti microalloyed high strength IF steel sheet was used to study the effect of annealing temperature on the microstructures,mechanical properties and textures.The experimental results show that experimental steel is incomplete recrystallization at 750℃ annealing,but complete recrystallization from 780℃ to 870℃ under experimental conditions.When the annealing temperature was increased,the yield strength and tensile strength would gradually reduce,the plastic strain ratio and yield point elongation would gradually increase.The yield strength,tensile strength,elongation,the plastic strain ratio and the strain hardening exponent were approximate 300MPa,410MPa,36.5%,1.7 and 0.22 respectively under annealing temperature 810℃ to 840℃.When the annealing temperature was increased,the α-textures and γ-textures were gradually weakened,and the α-textures have a trend to {111} texture.Therefore,the suggestion of the optimal recrystallization annealing temperature is about 810℃ to 840℃ in industrial production.     

磷、钛对含磷IF高强钢织构的影响

借助电子背散射衍射(EBSD)技术,以罩退生产的冷轧Ti-IF钢及含磷Ti-IF高强钢为目标,分析不同磷、钛合金质量分数对产品特征织构的影响。结果表明,磷元素虽然有利于γ取向线上{111}〈112〉织构的增加,但也增加了组分强度差,不利于塑性应变比r值,并且磷元素对{111}织构发展的促进作用取决于钢中过剰钛的质量分数,过剩钛质量分数过高会促进FeTiP二相粒子的析出,从而阻碍{111}取向再结晶晶粒的长大,弱化{111}面织构的强度。研究结果对该材料合金成分的调整起到了指导作用。为了保证所生产的含磷IF高强钢获得一定的强度,同时兼备良好的冲压性能,应降低IF钢中的钛质量分数,适当加入铌以弥补因钛减少对间隙原子固定产生的影响。     

Orientation imaging microscopy studies of recrystallization in interstitial-free steel

The origin of the γ fiber recrystallization texture in interstitial-free (IF) steel developed during continuous annealing has been investigated by scanning electron microscopy (SEM) and orientation imaging microscopy (OIM). Nucleation of {111∼<uvw> oriented crystals occurs in deformation banded γ grains and therefore a comprehensive study of microstructure of cold-rolled IF steel in the sections perpendicular to the rolling and transverse directions (TDs) and the rolling plane (RP) has been carried out to understand the formation, geometry, and microstructural features of recrystallization. The RP section gave abundant evidence of orientation gradients formed in γ oriented grains that had been subject to orientation splitting to give deformation bands. These orientation gradients across a single grain are around 5 to 30 deg and this orientation difference is sufficient to form nuclei with mobile interfaces during annealing and hence to create chains of γ oriented new grains in the original hot band γ grain envelopes. A grain impingement model requiring orientation pinning is then proposed to explain how these grains, contained in deformed γ grain envelopes, grow out into their neighbors to dominate the final recrystallization texture of IF steel. The α deformed grains contain only small lattice curvatures, and therefore in-grain nucleation is rare. These grains are mostly consumed by invading γ grains toward the end of the recrystallization process.