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选择性激光熔化技术中增材制造过程残余应力演变综述

A Review of the Evolution of Residual Stresses in Additive Manufacturing During Selective Laser Melting Technology.

作者信息

Bian Peiying, Jammal Ali, Xu Kewei, Ye Fangxia, Zhao Nan, Song Yun

机构信息

Xi'an Key Laboratory on Intelligent Additive Manufacturing Technologies, Shaanxi Key Laboratory of Surface Engineering and Remanufacturing, Xi'an University, Xi'an 710065, China.

School of Materials Science and Engineering, Xi'an Jiaotong University, Xi'an 710018, China.

出版信息

Materials (Basel). 2025 Apr 9;18(8):1707. doi: 10.3390/ma18081707.

DOI:10.3390/ma18081707
PMID:40333274
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12028742/
Abstract

Residual stress (RS) is one of the main reasons for component failure during an additive manufacturing (AM) process, especially using selective laser melting (SLM) technology. This paper reviews RS's investigation methods, formation mechanisms and regularities of distribution. When considering recent research progress, studies indicate that the dominant stress is primarily attributed to thermal stress induced by significant laser temperature gradients during the rapid melting and forming process, which subsequently transforms into RS upon cooling to room temperature, as verified by simulation and experiments. Then, the distribution regularities of RS are analyzed. SLM RS gradually increases when it is measured from the surface layer to the substrate. In the plane direction, at the center and edge of the part, tensile stresses are found; as for the middle area, which is the transition area of compressive stress, the whole plane stress remains in an equilibrium state. Based on the forementioned conclusions, the three-dimensional distribution diagram of RS on the sample was constructed. Finally, the strategic approaches for stress mitigation are briefly discussed. The excessive stress in forming can be reduced by process parameter matching, and the RS can be greatly remitted by pre-treatment/post-treatment, so as to improve the quality of formed parts. This review provides a valuable theoretical basis for practical applications of SLM.

摘要

残余应力(RS)是增材制造(AM)过程中部件失效的主要原因之一,尤其是在使用选择性激光熔化(SLM)技术时。本文综述了残余应力的研究方法、形成机制和分布规律。考虑到近期的研究进展,研究表明,主要应力主要归因于快速熔化和成型过程中由显著激光温度梯度引起的热应力,随后在冷却至室温时转变为残余应力,这已通过模拟和实验得到验证。然后,分析了残余应力的分布规律。从表层到基体测量时,SLM残余应力逐渐增加。在平面方向上,在零件的中心和边缘发现拉应力;至于中间区域,即压应力的过渡区域,整个平面应力保持平衡状态。基于上述结论,构建了样品上残余应力的三维分布图。最后,简要讨论了减轻应力的策略方法。通过工艺参数匹配可以降低成型过程中的过大应力,通过预处理/后处理可以大大缓解残余应力,从而提高成型零件的质量。本综述为SLM的实际应用提供了有价值的理论基础。

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