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电子束熔炼制造的Ti-6Al-4V实心样品的单调和疲劳行为:实验、分析与数值研究

Monotonic and Fatigue Behavior of EBM Manufactured Ti-6Al-4V Solid Samples: Experimental, Analytical and Numerical Investigations.

作者信息

Radlof Wiebke, Benz Christopher, Heyer Horst, Sander Manuela

机构信息

Institute of Structural Mechanics, Faculty of Mechanical Engineering and Marine Technology, University of Rostock, 18059 Rostock, Germany.

出版信息

Materials (Basel). 2020 Oct 17;13(20):4642. doi: 10.3390/ma13204642.

DOI:10.3390/ma13204642
PMID:33080913
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7603216/
Abstract

The present study aims to carry out an experimental, analytical and numerical investigation of the monotonic and fatigue performance of electron beam melted Ti-6Al-4V structures. Therefore, tensile tests, multiple step tests and strain-life tests were performed on machined EBM Ti-6Al-4V solid samples. An elastic-plastic material model in combination with a numerical damage model was examined according to the experimental tensile tests. Analytical models proposed by Ramberg and Osgood, as well as Coffin and Manson were obtained to describe the cyclic stress-strain curves and strain-life curves, respectively. The fracture surfaces of the tested samples and the influence of different build directions were analyzed. A prediction of the static and fatigue material properties is of particular importance, e.g., for the safe application of additively manufactured load-bearing implant structures. Based on the determined analytical and numerical models, the material and product behavior of complex electron beam melted structures under cyclic loading and fatigue life determination can be investigated in the early stages of the product development process.

摘要

本研究旨在对电子束熔化的Ti-6Al-4V结构的单调和疲劳性能进行实验、分析和数值研究。因此,对加工后的电子束熔化Ti-6Al-4V实心样品进行了拉伸试验、多步试验和应变寿命试验。根据实验拉伸试验,研究了弹塑性材料模型与数值损伤模型相结合的情况。分别获得了Ramberg和Osgood以及Coffin和Manson提出的解析模型,以描述循环应力-应变曲线和应变寿命曲线。分析了测试样品的断口表面以及不同构建方向的影响。例如,对于增材制造的承重植入物结构的安全应用,预测静态和疲劳材料性能尤为重要。基于所确定的解析和数值模型,可以在产品开发过程的早期阶段研究复杂电子束熔化结构在循环载荷下的材料和产品行为以及疲劳寿命确定。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cdc1/7603216/7020f392809e/materials-13-04642-g013.jpg
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Materials (Basel). 2018 Mar 31;11(4):537. doi: 10.3390/ma11040537.
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The relationships between deformation mechanisms and mechanical properties of additively manufactured porous biomaterials.
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