m23c6碳化物对退火420不锈钢非均匀应变发展的影响

J. Hidalgo, M. Vittorietti, H. Farahani, F. Vercruysse, R. Petrov, J. Sietsma
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引用次数: 22

摘要

在许多工程过程中,了解金属合金中不同组织特征导致的局部应变增强和晶格畸变是至关重要的。非均相应变的发展不仅在材料的加工硬化过程中起着重要作用,而且在材料的再结晶、损伤继承和断裂等过程中也起着重要作用。分离析出相对非均质应变发展的贡献可能具有挑战性,因为存在晶界或其他可能导致模糊解释的微观结构特征。本文结合电子背散射衍射测量的局部应变的统计分析和基于晶体塑性的模拟来确定M23C6碳化物对退火后AISI 420钢变形的影响。结果表明,碳化物在低塑性应变下通过主要的长程相互作用机制比纯铁素体组织提供更有效的硬化。碳化物不仅通过与铁素体基体的弹性不相容直接影响局部应变,而且还通过铁素体晶粒之间的空间相互作用直接影响局部应变。晶界处的碳化物促进了铁素体晶界附近应变的发展。然而,在碳化物和铁素体晶界密度较高的区域,碳化物和晶界对高局部应变的积极作用被减弱。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Influence of M 23C 6 Carbides on the Heterogeneous Strain Development in Annealed 420 Stainless Steel
Understanding the local strain enhancement and lattice distortion resulting from different microstructure features in metal alloys is crucial in many engineering processes. The development of heterogeneous strain not only plays an important role in the work hardening of the material but also in other processes such as recrystallization and damage inheritance and fracture. Isolating the contribution of precipitates to the development of heterogeneous strain can be challenging due to the presence of grain boundaries or other microstructure features that might cause ambiguous interpretation. In this work a statistical analysis of local strains measured by electron back scatter diffraction and crystal plasticity based simulations are combined to determine the effect of M23C6 carbides on the deformation of an annealed AISI 420 steel. Results suggest that carbides provide a more effective hardening at low plastic strain by a predominant long-range interaction mechanism than that of a pure ferritic microstructure. Carbides not only influence local strain directly by elastic incompatibilities with the ferritic matrix, but also the spatial interactions between ferrite grains. Carbides placed at the grain boundaries enhanced the development of strain near ferrite grain boundaries. However the positive effect of carbides and grain boundaries to develop high local strains is mitigated at regions with high density of carbides and ferrite grain boundaries.
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