研究了Fe-18Mn低C高Mn TRIP/TWIP钢在应变速率范围为1.67×10-4-103s-1的室温拉伸实验过程中力学性能和组织的变化.在准静态拉伸应变速率范围内(1.67× 10-4-1.67× 10-1s-1),应变速率对高Mn TRIP/TWIP钢的抗拉强度产生逆效应,随着应变速率的加快,抗拉强度和延伸率都降低;而在动态拉伸应变速率范围内(101-103s-1),应变速率对高Mn TRIP/TWIP钢的延伸率产生逆效应,抗拉强度和延伸率都随着应变速率的加快而增加;在应变速率为103s-1时,高Mn TRIP/TWIP钢抗拉强度可达到957MPa,延伸率达到55.8%,具有较好的综合力学性能;随着应变速率的提高,马氏体转变量减少,孪生变形向多个方向发展.采用SEM,TEM和XRD等方法对变形前后的组织进行了分析,在所有应变速率范围内的拉伸变形过程中都产生了奥氏体向马氏体转变和形变孪晶,并且在应变速率为103s-1的高速拉伸过程中产生绝热温升效应,使得基体软化.
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