Fracture and fatigue in additively manufactured metals
Additive manufacturing (AM) of metallic components offers many advantages over conventional manufacturing methods, most notably design freedom at little material waste. Consequently, there is significant current interest in the manufacturing aspects of a wide variety of structural alloys. Concomitan...
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sg-ntu-dr.10356-1625392022-10-28T05:34:51Z Fracture and fatigue in additively manufactured metals Becker, Thorsten Hermann Kumar, Punit Ramamurty, Upadrasta School of Mechanical and Aerospace Engineering Engineering::Mechanical engineering Fracture Toughness Fatigue Crack Growth Additive manufacturing (AM) of metallic components offers many advantages over conventional manufacturing methods, most notably design freedom at little material waste. Consequently, there is significant current interest in the manufacturing aspects of a wide variety of structural alloys. Concomitantly, establishing the processing – microstructure – mechanical performance relations, in conjunction with the attributes such as flaws, residual stresses, and mesostructures inherent to the AM processes, is critical for the widespread adoption of structural metallic components made using AM. Keeping this in view, a comprehensive review of the current understanding of the structure-property correlations in AM alloys is provided here. Unique aspects of the microstructures of the AM alloys, process-related attributes, and their effect on the tensile, fracture, fatigue crack growth, and unnotched fatigue properties are highlighted, with emphasis on the interplay between the microstructures and process attributes in determining the structural integrity of AM alloys in terms of properties such as near-threshold fatigue crack growth rate, fracture toughness, and fatigue strength. These aspects are contrasted with respective structure-property correlations in wrought or cast alloys. Strategies employed for improving the damage tolerance of the alloys through either improvisation of the processing conditions during AM or via post-processing treatments such as annealing, hot-isostatic pressing, and shot peening, are summarized. The existing gaps in understanding fatigue and fracture in AM alloys, which are critical for widespread deployment and reliable design of engineering components, are identified; such gaps are expected to provide future avenues for research in this area. THB acknowledges funding from the South African Department of Science and Innovation (DSI) through the Collaborative Program for Additive Manufacturing (CPAM). PK and UR acknowledge funding from A∗STAR through the Structural Metals and Alloys Programme (No. A18B1b0061). 2022-10-28T05:27:04Z 2022-10-28T05:27:04Z 2021 Journal Article Becker, T. H., Kumar, P. & Ramamurty, U. (2021). Fracture and fatigue in additively manufactured metals. Acta Materialia, 219, 117240-. https://dx.doi.org/10.1016/j.actamat.2021.117240 1359-6454 https://hdl.handle.net/10356/162539 10.1016/j.actamat.2021.117240 2-s2.0-85113387648 219 117240 en Acta Materialia © 2021 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved. |
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Engineering::Mechanical engineering Fracture Toughness Fatigue Crack Growth Becker, Thorsten Hermann Kumar, Punit Ramamurty, Upadrasta Fracture and fatigue in additively manufactured metals |
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Additive manufacturing (AM) of metallic components offers many advantages over conventional manufacturing methods, most notably design freedom at little material waste. Consequently, there is significant current interest in the manufacturing aspects of a wide variety of structural alloys. Concomitantly, establishing the processing – microstructure – mechanical performance relations, in conjunction with the attributes such as flaws, residual stresses, and mesostructures inherent to the AM processes, is critical for the widespread adoption of structural metallic components made using AM. Keeping this in view, a comprehensive review of the current understanding of the structure-property correlations in AM alloys is provided here. Unique aspects of the microstructures of the AM alloys, process-related attributes, and their effect on the tensile, fracture, fatigue crack growth, and unnotched fatigue properties are highlighted, with emphasis on the interplay between the microstructures and process attributes in determining the structural integrity of AM alloys in terms of properties such as near-threshold fatigue crack growth rate, fracture toughness, and fatigue strength. These aspects are contrasted with respective structure-property correlations in wrought or cast alloys. Strategies employed for improving the damage tolerance of the alloys through either improvisation of the processing conditions during AM or via post-processing treatments such as annealing, hot-isostatic pressing, and shot peening, are summarized. The existing gaps in understanding fatigue and fracture in AM alloys, which are critical for widespread deployment and reliable design of engineering components, are identified; such gaps are expected to provide future avenues for research in this area. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Becker, Thorsten Hermann Kumar, Punit Ramamurty, Upadrasta |
| format |
Article |
| author |
Becker, Thorsten Hermann Kumar, Punit Ramamurty, Upadrasta |
| author_sort |
Becker, Thorsten Hermann |
| title |
Fracture and fatigue in additively manufactured metals |
| title_short |
Fracture and fatigue in additively manufactured metals |
| title_full |
Fracture and fatigue in additively manufactured metals |
| title_fullStr |
Fracture and fatigue in additively manufactured metals |
| title_full_unstemmed |
Fracture and fatigue in additively manufactured metals |
| title_sort |
fracture and fatigue in additively manufactured metals |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/162539 |
| _version_ |
1749179235691397120 |