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含铌微合金高强度钢Q345C连铸坯的热塑性 被引量:10

Hot Ductility of Niobium-Microalloyed High Strength Steel Q345C Slab
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摘要 通过Gleeble-2000试验机研究了Q345C钢连铸坯的高温热塑性。利用扫描电镜、金相显微镜、透射电镜观察了第Ⅰ、Ⅲ脆性温度区内拉伸试样断口部位的显微组织及形貌,分析了动态再结晶、相变、析出物等对微合金化钢高温延塑性的影响。结果表明:在1×10-3/s应变速率下,Q345C钢存在两个脆性温度区,即第Ⅰ脆性区(1 200~1 300℃)和第Ⅲ脆性区(600~875℃),无第Ⅱ脆性区出现;最高塑性出现在1 050℃左右,断面收缩率(Z)达到85.8%;在第Ⅲ脆性区,沿奥氏体晶界析出膜状铁素体抗拉能力较低,晶界处存在夹杂物以及微合金元素的析出物,是钢的热塑性降低的主要原因。 Hot ductility of continuous casting Q345C slabs was tested by Gleeble-2000 thermal/strain simulation ma- chine. Using scanning electron microscopy, metalloscopy and transmission electron microscopy, morphology eharac teristics and microstructure of fracture surface of tensile specimen in Brittle temperature zone Ⅰ and Ⅲ were ob served. Influences of dynamic recrystallization, phase change and precipitate on hot ductility of the niobium- micro-alloyed steel were analyzed. The results showed that: at the 1× 10^-3/s strain rate, there are two low ductility zones, namely brittle zone i (1200 1300℃) and brittle zone Ⅲ(600 875 ℃) ,the brittle zone Ⅱ does not exist; the maximum ductility is around 1 050 ℃ and area reduction (Z)reached 85.80/00; in brittle zone Ⅲ , membranous lower tensile strength of ferrite along austenite grain boundaries, and the existence of inclusions and precipitates of micro- alloying elements in the grain boundaries is the main reasons for lower ductility of Q345C steel.
作者 王生朝 赵刚 鲍思前 石海宁 邓深 张海洲
机构地区 武汉科技大学材料与冶金学院 柳州钢铁集团公司技术中心 广西冶金研究院合金材料研究所
出处 《钢铁》 CAS CSCD 北大核心 2012年第1期74-77,共4页 Iron and Steel
基金 湖南省科学技术厅科技计划资助项目(2011GK3147)
关键词 Q345C 断面收缩率 连铸 板坯 热塑性 Q345C area reduction (Z) continuous casting slab hot ductility
分类号 TF777 [冶金工程—钢铁冶金]
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