Connecting Diffraction-Based Strain with Macroscopic Stresses in Laser Powder Bed Fused Ti-6Al-4V-Reference-Cited by-同舟云学术

Connecting Diffraction-Based Strain with Macroscopic Stresses in Laser Powder Bed Fused Ti-6Al-4V

Published:2020-03-27 Issue:6 Volume:51 Page:3194-3204
ISSN:1073-5623
Container-title:Metallurgical and Materials Transactions A
language:en
Short-container-title:Metall Mater Trans A

Author:

Mishurova Tatiana,Artzt Katia,Haubrich Jan,Evsevleev Sergei,Evans Alexander,Meixner Matthias,Munoz Itziar Serrano,Sevostianov Igor,Requena Guillermo,Bruno Giovanni

Abstract

AbstractThe laser powder bed fusion (LPBF) production process often results in large residual stress (RS) in the parts. Nondestructive techniques to determine RS are badly needed. However, a reliable quantification of macro-RS (i.e., stress at the component level) by means of diffraction-based techniques is still a great challenge, because the link between diffraction-based strain and macro-RS is not trivial. In this study, we experimentally determine (by means of in-situ synchrotron radiation diffraction) this link for LPBF Ti-6Al-4V. We compare our results with commonly used models to determine the so-called diffraction elastic constants (DECs). We show that LPBF materials possess different DECs than wrought alloys, simply because their microstructural and mechanical properties are different. We also show that the existing models can be used to calculate DECs only if high accuracy of the RS values is not required. If the peculiarities of the microstructure have to be taken into account (as is the case of additively manufactured materials), a radically new approach is desirable.

Publisher

Springer Science and Business Media LLC

Subject

Metals and Alloys,Mechanics of Materials,Condensed Matter Physics

Link

http://link.springer.com/content/pdf/10.1007/s11661-020-05711-6.pdf

Reference50 articles.

1. 1. Jamison L. Bartlett and Xiaodong Li: Addit. Manufact., 2019, vol. 27, pp. 131–49.

2. 2. Bey Vrancken, Victoria Cain, Rob Knutsen, and Jan Van Humbeeck: Scripta Mater., 2014, vol. 87, pp. 29–32.

3. 3. Peter Mercelis and Jean‐Pierre Kruth: Rap. Prototyp. J., 2006, vol. 12, pp. 254–65.

4. 4. T. Thiede, S. Cabeza, T. Mishurova, N. Nadammal, A. Kromm, J. Bode, C. Haberland, and G. Bruno: Mater. Perfor. Charact., 2018, vol. 4, pp. 717–35.

5. 5. T. Mishurova, S. Cabeza, K. Artzt, J. Haubrich, M. Klaus, C. Genzel, G. Requena, and G. Bruno: Materials, 2017, vol. 10, pp. 348–62.

Cited by 14 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Understanding the hot isostatic pressing effectiveness of laser powder bed fusion Ti-6Al-4V by in-situ X-ray imaging and diffraction experiments;Scientific Reports;2023-10-27

2. Controlling the Structure and Properties of Metal- and Polymer-Based Composites Fabricated by Combined 3D Methods;Advanced Structured Materials;2023

3. Micromechanical behavior of annealed Ti-6Al-4V produced by Laser Powder Bed Fusion;European Journal of Materials;2022-05-02

4. Laser powder bed fusion additive manufacturing (LPBF-AM): the influence of design features and LPBF variables on surface topography and effect on fatigue properties;Critical Reviews in Solid State and Materials Sciences;2022-03-08

5. Laser Powder Bed Fusion and Selective Laser Melted Components Investigated with Highly Penetrating Radiation;Fatigue of Aircraft Structures;2021-12-01