硅钢资料

通过固溶度积公式计算及热模拟实验,对不同热装和加热温度条件下的无取向硅钢铸坯中析出相进行了研究.在低于950℃热装时,铸坯中AlN的析出量和尺寸不再变化,但MnS和AlN-MnS的数量及平均尺寸随着热装温度降低而进一步增加,并在温度低于600℃时达到最大值后保持不变.与1200℃相比,1100℃加热的铸坯中AlN、MnS的总固溶量相对更少.相比850℃热装,600℃热装再加热到1100℃的铸坯中AlN和MnS的总固溶量更少,且AlN和MnS尺寸更大.合适的热装温度和加热温度分别为600℃和1100℃. Based on solubility product calculation and thermal simulation experiments,precipitated phases in continuous casting slabs of non-oriented silicon steel were systematically studied at different hot charging and heating temperatures.When the hot charging temperature is below 950 ℃,the content and size of AlN remain unchanged,but the quantity and size of MnS and AlN-MnS increase when the hot charging temperature decreases,reach maximum and remain unchanged when the hot charging temperature is belo... 

本发明提供虽然为薄壁但磁特性优异的方向性电磁钢板的制造方法。本发明的一个方案提供一种方向性电磁钢板的制造方法，其包括热轧工序、任选的热轧板退火工序、酸洗工序、冷轧工序、一次再结晶退火工序、成品退火工序和平坦化退火工序，在酸洗工序中，使用包含0.0001g/L～5.00g/L的Cu的酸洗溶液，冷轧钢板的板厚为0.15mm～0.23mm，一次再结晶退火工序的升温工序中的30℃～400℃的温度区域的平均升温速度超过50℃/秒且为1000℃/秒以下。

本发明揭示了一种无取向硅钢及其生产方法。所述生产方法包括：按照Si0.8～1.1％、Mn0.2～0.4％、不添加Sn和Sb进行炼钢，并制坯；将铸坯加热到1060～1120℃并保温150min以上，而后轧成厚度40～45mm的中间坯，再经精轧、卷取得到厚度为3.00±0.25mm的热轧卷板，精轧开轧温度≤872℃+1000*(11*[Si]‑14*[Mn]+21*[Al])；精轧终轧温度≤820℃，卷取温度≤560℃；常化、酸连轧，得到厚度为0.500±0.005mm的冷硬卷，常化温度850～900℃；成品退火温度820～880℃，退火后经冷却、涂层和精整，得到无取向硅钢。

利用OM、EBSD等手段研究了热轧板两段式正火时在700℃保温不同时间(0、10、30、60 min)对含Sb冷轧无取向电工钢磁性能的影响。结果表明,700℃保温10 min处理的样品铁损最小,磁感最高。对成品板的组织分析结果表明,试样的晶粒尺寸随700℃保温时间的延长先增大后减小,保温10 min时晶粒尺寸达到最大;分析成品试样织构发现,有利织构组分随700℃保温时间的延长先增加后减少,保温10 min时有利织构组分所占百分比最高。因此,含Sb冷轧无取向电工钢两段式正火时在700℃保温10 min时磁性能最好。 Effect of two-stage normalization on magnetic property of non-oriented electrical steel containing antimony was investigated by using optical microscope(OM) and electron back-scattered diffraction technology(EBSD).The experimental results show that the iron loss and magnetic permeability of the specimen insulated at 700 ℃ for 10 min are lowest and highest respectively.The grain size of the finish specimens increases first and then decreases with the increase of holding time.Similarly,the advanta... 

本发明公开了一种改善高牌号无取向硅钢表面色差缺陷的方法，属于冷轧卷板表面质量改进技术领域。所述方法为：将连铸坯依次进行热轧、常化、酸洗、单机架轧制和连续退火工序，其中按重量百分数计，所述的连铸坯含有如下成分：C＜0.003%、Si1.6~2.0%、Mn0.35~0.65%、Al0.35~0.65%、P＜0.02%、S＜0.0025%、余量为Fe和其他不可避免的杂质元素，所有成分合计100%；其中热轧工序的卷取温度为620~640℃。本发明所述方法能够降低带钢表面氧化铁厚度并改变带钢表面氧化铁结构，改善高牌号无取向硅钢表面色差缺陷。

为研究常化温度对热轧无取向硅钢组织与织构的影响,采用光学显微镜、背电子散射衍射技术研究了不同常化温度对其影响。结果表明,实验硅钢板在700～850℃温度下常化时,随常化温度的升高,晶粒尺寸增大,有利组分α织构增强,不利组分γ织构降低。对比研究了800℃和850℃常化热轧板CSL晶界分布图与取向差分布图,在本文研究条件下,Goss织构易在Σ=3,9的CSL晶界及晶粒取向差为30°～55°处形成。 The hot strips normalized at different temperatures were investigated by optical microscope and EBSD to study the effect of normalizing temperature on microstructure and texture of hot-rolled non-oriented silicon steel sheets.The results show that the grain size increases,the intensity of α-fibre texture increases,and the γ-fibre texture decreases when the hot strips are normalized at the 700-850 ℃.And CSL boundaries of Σ=3 and 15,and misorientation angles between 30° and 55° are more likely rel... 

通过观察冲剪边缘组织,测量冲剪边缘的显微硬度、残余应力的分布情况和磁性能的变化研究了冲剪加工对无取向硅钢50WW800边缘组织和磁性能的影响。对冲剪后硅钢片进行750℃退火,分析退火对组织和磁性能的影响。结果表明,硅钢片剪切边缘会存在0.4 mm的形变硬化层,边缘应力大,铁损增加。退火后变形减小,形变硬化层变小,残余应力大幅度减少,铁损减少。 The influence of punching process on cutting edge microstructure and magnetic properties of non-oriented silicon steel 50WW800was studied by observing microstructure and measuring microhardness near cutting edge.The residual stress distribution in the silicon steel tooth and magnetic properties were measured.Effect of annealing at 750 ℃ on microstructure and magnetic properties of the silicon steel was analyzed.The results show that a cut-edge hardening layer up to 0.4 mm is observed,residual st... 

分析了冲裁硅钢芯片时出现的质量问题,针对影响硅钢芯片冲裁质量的4大因素——人、原材料状态、工艺和工装进行了工艺试验和分析,根据原材料状态的差异,采用不同工艺方案,特别是如何合理选择冲裁模具间隙,解决了硅钢芯片冲裁时产生的主要质量问题,使冲裁的硅钢芯片达到最佳质量状态,并满足硅钢芯片的使用性能。 The problems occurred during silicon steel chip punching and the factors that affect the quality of silicon steel chip punching were analyzed,the factors include 4aspects,that is,people,raw material status,process and frock,at the same time,process tests and analysis aimed at the factors that affect punching quality were did,according to the difference of raw material status,corresponding process schedules wee taken,especially in how to reasonably select punching dies clearance,which solved the ... 

研究了热处理工艺(退火温度、保温时间、冷却方式)对含Mn的Fe-6.5wt%Si高硅钢热轧带的显微组织及硬度的影响。结果表明,退火温度对Fe-6.5wt%Si合金的组织和显微硬度均有较大影响,随退火温度升高,平均晶粒尺寸和显微硬度均明显增大。小于1 h退火时,晶粒长大缓慢,而长时间(>1 h)退火时,一些次表层晶粒将发生异常长大。水冷组织比空冷组织略细小,但水冷显著降低了显微硬度。Mn含量提高能抑制850℃退火时晶粒的长大,并且促进退火后高硅钢的软化。 The influences of heat treatment process(annealing temperature,heating time,cooling methods) on the microstructure and microhardness of Fe-6.5wt%Si high silicon steel containing manganese for hot rolled strip were studied.The results show that the annealing temperature has a great effect on the microstructure and microhardness of Fe-6.5wt%Si alloy,and as the annealing temperature increases,the average grain sizes and microhardness will significantly increase.When annealing time for less than 1 h... 

本实用新型公开了一种高磁感取向硅钢加工用拉伸装置，涉及硅钢加工技术领域，包括安装架，所述安装架的后端安装有两个驱动电机，两个所述驱动电机的输出端均连接有下输送辊，所述下输送辊的左侧设置有下调节辊，所述下调节辊和下输送辊的末端均固定有限位圈，所述下输送辊的上方设置有上输送辊，所述上输送辊的左侧设置有上调节辊，所述上调节辊和下调节辊的内部均设置有连接杆，所述连接杆的外表面设置有卡块。该高磁感取向硅钢加工用拉伸装置通过设置的驱动电机，能够带动下输送辊转动，从而对工件进行输送，通过设置的连接杆和卡块，使得下输送辊转动时能够带动下调节辊转动，提高工件的输送效率。

本发明特别涉及一种控制边部质量的低牌号无取向硅钢的热轧生产方法，属于无取向硅钢热轧生产技术领域，方法包括：将低牌号无取向硅钢的板坯进行第一次粗轧，将第一次粗轧后的板坯进行第二次粗轧，其中，在第二次粗轧机前的立辊上设置立辊润滑装置，所述立辊润滑装置向所述立辊供给的润滑油的油量为100mL/min‑400mL/min；将第二次粗轧后的板坯进行精除鳞、精轧和卷取，获得边部质量合格的热轧卷；保证良好的立辊辊面状态，可有效解决边部粗糙，有效解决了低牌号无取向硅钢边部粗糙状态，极大的提高了冷轧后工序毛边轧制率，提高了硅钢全工序成材率。

试验2.3Si无取向硅钢(/%:0.003C,2.30Si,0.16Mn,≤0.020P,≤0.005S,0.54Al)冷轧板由常化和未常化的2.5 mm热轧板冷轧至0.6 mm(压下率76%),经750~950℃2.5 min中间退火后再冷轧至0.5 mm(压下率16.7%),成品板经890℃+960℃2.5 min退火。研究了中间退火温度对该钢晶粒尺寸、织构和磁性能的影响。结果表明,随中间退火温度的升高,二次冷轧前晶粒和成品晶粒增大,成品中不利织构组分{111}和{112}减弱,磁性能得到改善。热轧板经过常化时的磁性能明显好于未经常化时的磁性能,但中间退火温度较高时常化对磁性能的有利作用减弱。 The test cold sheet of 2.3Si non-oriented silicon steel(/%:0.003C,2.30Si,0.16Mn,≤0.020P,≤0.005S,0.54Al) is first cold-rolled from normalized and un-normalizing 2.5 mm hot-rolled plate to 0.6 mm sheet(reduction 76%),then intermediate annealed at 750~950℃ for 2.5 min and double cold-rolled to 0.5 mm sheet(reduction16.7%),the finished sheet annealed at 890℃+960℃ for 2.5 min.Effect of the intermediate annealing temperature on grain size,texture and magnetic performance of the steel has been studied....