In-Situ Observation of the Multi-phase Transition and Microstructure Evolution of 22MnB5 Steel

Ce Liang, Guangxin Song, Wanlin Wang, Jie Zeng
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Abstract

An experimental investigation was conducted to elucidate the impact of cooling rate on the microstructure evolution of boron-containing steel 22MnB5 by in-situ observation using the confocal laser scanning microscope (CLSM). The observations manifested distinct multi-phase formation of reconstructive grain boundary allotriomorphic ferrite (GBA) and pearlite (P) to sympathetic intergranular acicular ferrite (IAF) and bainite (B), as well as the displacive martensite (M) under different predefined cooling rates (1, 10, and 20 °C/s). Notably, as the cooling rate escalated from 1 to 10 or 20 °C/s, the starting and finishing phase transition temperature decreased significantly. For the 22MnB5 steel cooled at 1 °C/s, the solid phase transition sequence followed γ→GBA→P→IAF, while for the steel cooled at 10 and 20 °C/s, the transition sequence shifted to γ→B→M. Additionally, in the sample cooled at 20 °C/s, the bainite lath spacing reduced and more small size martensite appeared as the mechanical stabilization of austenite. Simultaneously, the dislocation density increased compared to the slow cooled samples, primarily due to the elevated nucleation rate from austenite to ferrite and larger internal stress induced by the enhancing cooling intensity.

Graphical Abstract

Abstract Image

原位观测 22MnB5 钢的多相转变和显微结构演变
通过使用激光共聚焦扫描显微镜(CLSM)进行原位观察,进行了一项实验研究,以阐明冷却速度对含硼钢 22MnB5 显微结构演变的影响。观察结果表明,在不同的预定冷却速率(1、10 和 20 °C/s)下,从重构晶界异形铁素体(GBA)和波来石(P)到共生晶间针状铁素体(IAF)和贝氏体(B)以及置换马氏体(M)形成了明显的多相。值得注意的是,随着冷却速率从 1 ℃/秒上升到 10 ℃/秒或 20 ℃/秒,起始相变温度和终结相变温度显著降低。对于以 1 °C/s 冷却的 22MnB5 钢,固相转变序列遵循 γ→GBA→P→IAF,而对于以 10 和 20 °C/s 冷却的钢,转变序列转向 γ→B→M。此外,在以 20 °C/s 冷却的试样中,贝氏体板条间距减小,出现了更多的小尺寸马氏体作为奥氏体的机械稳定剂。同时,与慢速冷却的样品相比,位错密度增加了,这主要是由于奥氏体向铁素体的成核率升高,以及冷却强度增加引起的内应力增大。
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