锻压技术

温度对GH4169镍基高温合金形变过程位错演化的影响

英文标题：Effects of temperature on dislocation evolution for Ni-based superalloy GH4169 during deformation process

作者：焦磊石科学孙晓峰朱波田晨超李星辰

分类号：TG142

出版年,卷(期):页码：2024,49(12):217-223

摘要：

摘要：建立了基于分子动力学的GH4169镍基高温合金计算模型，并通过300、600和920 K温度条件下的单轴拉伸过程仿真分析，讨论了温度对模型内部位错演化与力学行为的影响。结果表明：室温（300 K）及高温(600和920 K)环境下,GH4169镍基高温合金弹性变形范围内的应力-应变曲线差别不大，说明合金具有良好的高温（920 K）抗性；形变过程中FCC结构原子占比逐渐降低，且温度越高，FCC结构原子占比的降低速率越低；依据体系内部原子结构的演化可将整体形变过程分为弹性区、塑性激活区及应力释放区,进入塑性激活区后，形成大量Shockley不全位错，且在后续形变过程中其密度逐渐降低，并逐渐演化为其他类型的位错。此研究为镍基高温合金形变时材料的微观组织变化规律提供一定理论指导。

Abstract: A calculation model for Ni-based superalloy GH4169 based on molecular dynamics was established to simulate and analyse the uniaxial tensile process at the temperature of 300, 600 and 920 K, and the influences of temperature on the dislocation evolution and mechanical behavior inside the model were discussed. The results show that the stress-strain curves of Ni-based superalloy GH4169 in the elastic deformation range at room temperature(300 K) and high temperature(600 and 920 K) are not significantly different, which proves that Ni-based superalloy GH4169 has good resistance to high temperature (920 K). During the deformation process, the proportion of FCC structure atoms gradually decreases, and the higher the temperature, the slower the decreasing rate of FCC structure atom proportion. According to the evolution of atomic structure within the system, the overall deformation process can be divided into elastic zone, plastic activation zone and stress release zone. After entering the plastic activation zone, a large number of Shockley incomplete dislocations are formed, and the density of Shockley incomplete dislocations is gradually decreased during the subsequent deformation process, evolving into other types of dislocations.This study provides theoretical guidance for the microstructural changes of Ni-based superalloy during deformation.

基金项目：

无

作者简介：焦磊（1985），男，硕士，高级工程师 E-mail：jiaolei.21@163.com

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