马氏体条件下中锰钢临界间退火过程中奥氏体形成和渗碳体溶解

J. Mueller, Xiaohua Hu, Xiang Sun, Yan-guang Ren, Jin-Kyung Choi, Carol E. Barker, J. Speer, D. Matlock, E. Moor
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引用次数: 26

摘要

摘要采用原位高能x射线衍射(HEXRD)、膨胀法和金相法研究了Fe-0.19C-4.39Mn钢在马氏体初始条件下的临界间退火过程中的组织演变。使用thermocalc®的DICTRA™模块对等温保温过程中的奥氏体生长和溶质分配进行了三种不同的模拟。临界间退火后的显微组织表现为膜状残余奥氏体;然而,原位HEXRD表明,在加热到等温保温温度时,初始马氏体组织中的残余奥氏体已经分解,这表明在临界间退火过程中,可能通过新奥氏体的形核和生长产生膜状奥氏体,而不一定保留马氏体组织中的初始残余奥氏体膜。金相和原位HEXRD也表明,渗碳体是在加热过程中形成的,但在1800 s等温保温过程中不容易溶解,尽管在等温保温过程中奥氏体出现了相当大的生长,这表明在临界退火过程中奥氏体的形核和初始生长并不仅仅是由于碳分配而发生的。含渗碳体的模拟表明,在临界间退火过程中,奥氏体分数的增加最初与Mn分配有关,随后是渗碳体逐渐溶解引起的奥氏体生长。
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Austenite Formation and Cementite Dissolution During Intercritical Annealing of a Medium-Manganese Steel from a Martensitic Condition
Abstract In the present study, in situ high-energy X-ray diffraction (HEXRD), dilatometry, and metallography were conducted for the purpose of understanding microstructure evolution during intercritical annealing of a Fe-0.19C-4.39Mn steel from a martensitic initial condition. Three different simulations for austenite growth and solute partitioning during isothermal holding were conducted using the DICTRA™ module of Thermo-Calc®. The microstructures after intercritical annealing exhibit film-like retained austenite; however, in situ HEXRD indicates that retained austenite in the initial martensitic microstructure had decomposed upon heating to the isothermal holding temperature, suggesting that film-like austenite may be generated during intercritical annealing via nucleation and growth of new austenite and without necessarily preserving initial retained austenite films in the martensitic microstructure. Metallography and in situ HEXRD also indicate that cementite had formed upon heating but did not readily dissolve during an 1800 s isothermal hold although considerable growth of austenite had occurred during the isothermal hold, suggesting that austenite nucleation and initial growth during intercritical annealing does not solely occur due to carbon partitioning. A simulation incorporating cementite suggests that the increase in austenite fraction during intercritical annealing initially occurs in association with Mn partitioning followed by austenite growth induced by gradual cementite dissolution.
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