复杂晶格几何体增材制造中的残余应力产生

IF 2.2 4区材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY

Journal of Materials Engineering and Performance Pub Date : 2024-02-21 DOI:10.1007/s11665-024-09229-5

Katie Bruggeman, Nathan Klingbeil, Anthony Palazotto

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引用次数: 0

摘要

摘要在增材制造（AM）过程中产生的残余应力会影响结构部件在预期应用中的机械性能。本研究对激光粉末床熔融（LPBF）工艺进行了热机械残余应力模拟，模拟对象包括简化（板状和立方体状）几何形状以及用 Inconel 718 制造的五种复杂晶格几何形状。这些模拟使用 Simufact Additive© 商业软件包进行，该软件包使用非线性有限元分析和逐层平均法确定残余应力。为了验证 Simufact Additive© 模拟的有效性，对板材和立方体几何形状的数值结果进行了收敛分析，并与文献中的残余应力实验结果进行了比较。随后比较了五种复杂晶格几何形状的残余应力数值结果。结果表明，晶格几何形状对残余应力的分布和大小有重要影响，这在某些应用中非常重要。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Residual Stress Generation in Additive Manufacturing of Complex Lattice Geometries

Residual stresses developed during additive manufacturing (AM) can influence the mechanical performance of structural components in their intended applications. In this study, thermomechanical residual stress simulations of the laser powder bed fusion (LPBF) process are conducted for both simplified (plate and cube-shaped) geometries as well as five complex lattice geometries fabricated with Inconel 718. These simulations are conducted with the commercial software package Simufact Additive^©, which uses a nonlinear finite element analysis and layer-by-layer averaging approach in determining residual stresses. To verify the efficacy of the Simufact Additive^© simulations, numerical results for the plate and cube-shape geometries are analyzed for convergence and compared to experimental residual stress results available in the literature. Numerical residual stress results are subsequently compared for five complex lattice geometries. Results suggest that lattice geometry can play a significant role in the distribution and magnitude of residual stresses, which are significant in some applications.

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来源期刊

Journal of Materials Engineering and Performance 工程技术-材料科学：综合

CiteScore

3.90

自引率

13.00%

发文量

1120

审稿时长

4.9 months

期刊介绍： ASM International''s Journal of Materials Engineering and Performance focuses on solving day-to-day engineering challenges, particularly those involving components for larger systems. The journal presents a clear understanding of relationships between materials selection, processing, applications and performance. The Journal of Materials Engineering covers all aspects of materials selection, design, processing, characterization and evaluation, including how to improve materials properties through processes and process control of casting, forming, heat treating, surface modification and coating, and fabrication. Testing and characterization (including mechanical and physical tests, NDE, metallography, failure analysis, corrosion resistance, chemical analysis, surface characterization, and microanalysis of surfaces, features and fractures), and industrial performance measurement are also covered