C和Mn元素配分行为对冷轧中锰TRIP钢组织性能的影响

采用冷轧+两相区温轧退火（CR+WR+IA）热处理工艺，研究了两相区退火时间对超细晶铁素体与奥氏体中组织形貌演变、C和Mn元素配分行为以及力学性能的影响。结果表明，冷轧试验钢经两相区形变退火处理后，获得了由铁素体、残余奥氏体或新生马氏体组成的超细晶复相组织。在645℃随退火时间的延长，形变马氏体向逆相变奥氏体配分的C、Mn元素增多，C、Mn元素富集位置增加，同时富Mn区形变马氏体回复再结晶现象明显；伴随少量碳化物溶解，试验钢的屈服强度由741持续降低到325MPa。两相区退火10min时，试验钢力学性能最佳，此时抗拉强度达到最大值1141MPa，断后伸长率及均匀伸长率分别为236%和181%，强塑积达到26928MPa·%。

Effect of C and Mn element partitioning behavior on#br#microstructure and properties of cold rolled medium manganese TRIP steel

The effect of intercritical annealing time on the microstructure evolution, C and Mn elements partitioning behavior, and mechanical properties of ultrafine grained ferrite and austenite was studied by means of a new heat treatment process of cold rolling followed by warm rolling and intercritical annealing at two phase region (CR+WR+IA). The results showed that the ultrafine grained multiphase microstructure composed of ferrite, retained austenite or fresh martensite was obtained after cold rolled experimental steel treated by intercritical deformation annealing. With prolonging the annealing time at 645℃, C and Mn elements constantly diffused from deformed martensite to reverted austenite, resulting in the increase in enrichment sites of C and Mn elements. Meanwhile, recrystallization phenomenon of deformed martensite was obvious in the Mn rich region. With a small amount of carbide precipitation and dissolution, the yield strength of experimental steel was continuously decreased from 741 to 325MPa. After intercritical annealing for 10min, the best comprehensive performance of experimental steel was reached. At this time, the tensile strength reached a maximum value of 1141MPa, the elongation after fracture and uniform elongation were 236% and 181%, respectively, and the product of strength and elongation reached 26928MPa·%.