共查询到18条相似文献,搜索用时 78 毫秒
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薄带连铸工艺是薄带生产中的一项新技术,其生产成本较低。在这项工艺中,能进行10~70%的冷轧,完全可省略热轧。有几家企业已经完成了生产设备的商业化改造,新产品目前正在试制当中。由于薄带连铸工艺的凝固过程比传统连铸工艺快,因此薄带连 相似文献
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采用商业有限元软件的传热模型,对304不锈钢板坯连铸过程中坯壳生长进行了数值模拟,计算了304不锈钢板坯在连铸过程中坯壳生长变化规律. 相似文献
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对304不锈钢连铸坯进行了解剖分析。分析结果表明:在25%的铸坯深振痕或渣坑缺陷试样中观察到了微裂纹或气孔。 相似文献
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以具有不同初始组织的Cr17铁素体不锈钢双辊连铸薄带为实验材料,分别进行相同的冷轧及退火处理,对织构演变进行了对比研究.结果表明:织构演变与薄带的初始组织、织构密切相关.柱状晶薄带具有显著的(001)//ND织构,等轴晶薄带则具有微弱的随机织构;两者经冷轧后都形成了较温和的α纤维织构及较均匀的γ纤维织构,但是,后者的α,γ纤维织构明显强于前者;经再结晶退火后,两者都能形成较均匀的γ纤维再结晶织构,但后者的γ纤维再结晶织构明显强于前者. 相似文献
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为了确定薄带连铸AISI304不锈钢凝固过程中残留铁素体的生成及转变行为,采用彩色金相、电解侵蚀、电子背散射衍射分析技术及X射线衍射分析等研究手段对双辊薄带连铸AISI304不锈钢凝固组织及残留铁素体特征进行了研究.结果表明AISI304不锈钢薄带的凝固组织由表层胞状晶区、中间柱状晶区和中心等轴晶区三部分组成.薄带表层胞状晶区内残留铁素体呈棒状,柱状晶区的残留铁素体形态为鱼骨状,中心等轴晶区的残留铁素体呈弯曲的树枝状;薄带的表层胞状晶区残留铁素体的质量分数为4.6%~6.6%,柱状晶区内的残留铁素体质量分数为3.6%~3.7%,中心等轴晶区内的残留铁素体质量分数为11.27%~11.34%;残留铁素体沿着厚度方向呈现\ 相似文献
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This study is about the latest advances in the optimization of the microstructure and properties of thin strip cast austenitic stainless steel (AISI 304, 1.4301). Concerning the processing steps the relevance of different thin strip casting parameters, in‐line forming operations, and heat treatments for optimizing microstructure and properties have been studied. The microstructures obtained from the different processing strategies were analysed with respect to phase and grain structures including the grain boundary character distributions via EBSD microtexture measurements, the evolution of deformation‐induced martensite, the relationship between delta ferrite and martensite formation in austenite, and the texture evolution during in‐line deformation. It is observed that different process parameters lead to markedly different microstructures and profound differences in strip homogeneity. It is demonstrated that the properties of strip cast and in‐line hot rolled austenitic stainless steels are competitive to those obtained by conventional continuous casting and hot rolling. This means that the thin strip casting technique is not only competitive to conventional routes with respect to the properties of the material but also represents the most environmentally friendly, flexible, energy‐saving, and modern industrial technique to produce stainless steel strips. 相似文献
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通过对304不锈钢连铸坯表面裂纹产生的原因如钢种特性、连铸过热度、冷却强度以及拉速等进行分析,并结合现场生产的实际情况,提出了消除304不锈钢连铸坯表面裂纹缺陷的措施,取得了良好的实际应用效果。 相似文献
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利用Gleeble-1500热模拟试验机对304L不锈钢的金属塑性变形抗力进行了试验研究。首先通过单道次压缩实验研究了变形温度、变形速率和变形程度对变形抗力的影响,合理选择变形抗力数学模型并给出待定系数,然后研究了试验的重复性和试样长度对试验结果的影响,最后通过双道次压缩实验研究了道次间的残余应变对变形抗力的影响并建立了在考虑残余应变影响条件下的变形抗力数学模型。该模型可为计算304L不锈钢的轧制力提供理论依据。 相似文献
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The microstructures of austenitic stainless steel strip were studied using color metallographic method and electron probe micro analysis (EPMA). In the cast strips, there are three kinds of solidification structures: fine cellular dendrite in the surface layer, equiaxed grains in the center and fine dendrite between them. The solidification mode in the surface layer is the primary austenite AF mode because of extremely high cooling rate, with the retained ferrite located around the primary cellular austenite. In the fine dendrite zone, the solidification mode of molten stainless steel changes to FA mode and the residual ferrite with fish-bone morphology is located at the core of the dendrite. The retained ferrite of equiaxed grains in the center is located in the center of broken primary ferrite dendrite with vermicular morphology. 相似文献