拉伸条件下 439 不锈钢的微观结构演变:相场模拟与实验

Yongbo Liu, Mingtao Wang, Qingcheng Liu, J. Jin, Qing Peng, Y. Zong
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引用次数: 0

摘要

结合相场模拟和实验验证,研究了退火张力对 439 铁素体不锈钢(FSS)微观结构演变的影响。研究揭示了拉伸应力下纹理的竞争机制。此外,还建立了包含各向异性晶界(GB)能和弹性能的相场模型。在本研究提出的二维 EBSD 表征基础上,采用三维重建策略创建了 439 FSS 的微观结构。弹性常数使用实际合金数据进行校准,并通过分子动力学模拟确定。最后,考虑到拉伸应力和各向异性 GB 能量效应,成功模拟了 439 FSS 中的晶粒粗化过程。结果表明,低角度晶界(LAGBs)的存在使晶粒尺寸分布偏离了希勒特模型的预测,并减缓了平均晶粒尺寸随时间的演变。与希勒特预测相比,在拉伸应力作用下的纹理系统中观察到晶粒尺寸分布有明显偏差。生长动力学结果表明,拉伸应力对晶粒生长的促进作用大于 GB 能量各向异性对微结构演变的阻碍作用。实验和模拟结果一致表明,在拉伸应力作用下,取向为 //ND 的晶粒比其他取向的晶粒具有更好的生长能力。这项研究为管理 FSS 的铁素体微观结构以提高其成型能力提供了新的见解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Microstructure evolution in 439 stainless steels under tensile: phase field simulation and experiment
A combination of phase-field simulations and experimental validation is utilized to examine the effect of annealing tension on the microstructure evolution of 439 ferrite stainless steel (FSS). The study reveals the competing mechanisms of texture under tensile stress. Furthermore, a phase field model that incorporates anisotropic grain boundary (GB) energy and elastic energy is established. The microstructure of 439 FSS is created using a 3D reconstruction strategy based on the 2D EBSD characterization proposed in this work. Elastic constants are calibrated using actual alloy data and determined through molecular dynamics simulations. Finally, simulations of the grain coarsening process in 439 FSS are successfully achieved, considering both tensile stress and anisotropic GB energy effects. The results reveal that the presence of low-angle grain boundaries (LAGBs) deviates from Hillert model predictions in terms of grain size distribution and slows down the average grain size evolution over time. A significant deviation in the grain size distribution, compared to Hillert predictions, is observed in the textured system under tensile stress. The results of growth kinetics indicate that tensile stress promotes grain growth more than GB energy anisotropy retards microstructure evolution. Both experiment and simulation results consistently demonstrate that grains with <111>//ND orientation experience a better growth proficiency compared to grains of other orientations under tensile stress. This investigation offers fresh insights into managing the ferritic microstructure of FSS to enhance its formability capabilities.
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