Modulating fracture toughness through processing-mediated mesostructure in additively manufactured Al-12Si alloy
Al-12Si alloy processed through additive manufacturing exhibits a complex hierarchical structure. At the mesoscale, its melt pool boundaries constitute a network of weak interfaces that provides preferred pathways for crack kinking, leading to both marked anisotropy and apparent enhancement in the f...
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sg-ntu-dr.10356-1626552022-11-02T02:54:19Z Modulating fracture toughness through processing-mediated mesostructure in additively manufactured Al-12Si alloy Jamshidian, Mostafa Promoppatum, Patcharapit Ramamurty, Upradrasta Jhon, Mark Hyunpong School of Mechanical and Aerospace Engineering Institute of Materials Research & Engineering, A*STAR, Engineering::Mechanical engineering Engineering::Materials Fracture Toughness Laser Powder Bed Fusion Al-12Si alloy processed through additive manufacturing exhibits a complex hierarchical structure. At the mesoscale, its melt pool boundaries constitute a network of weak interfaces that provides preferred pathways for crack kinking, leading to both marked anisotropy and apparent enhancement in the fracture energy. In this study, a multiscale cohesive zone-based computational model and a semi-analytical approach for kinked cracks are used to investigate the effect of melt pool configuration on fracture energy enhancement and anisotropy due to crack path tortuosity. We experimentally validate our methodology using fracture toughness testing of compact tension specimens, then systematically study the simultaneous effects of hatch spacing, layer thickness, and crack surface orientation on variations of the fracture energy. While the fracture energy increases with increasing hatch spacing and decreasing layer thickness, processing defects such as keyholing give practical limits to the melt pool geometry, limiting the fracture energy enhancement. We found that the fracture energy can be enhanced as high as a factor of two with an optimal crack surface orientation that is linearly proportional to the ratio of hatch spacing to layer thickness and varies between 60° and 100°. Agency for Science, Technology and Research (A*STAR) Published version This work was supported by the funding from A*STAR, Singapore via the Structural Metals and Alloys Programme (No. A18B1b0061). PP acknowledges the support from Thailand Science Research and Innovation (TSRI) under Fundamental Fund 2022 (Project: Advanced Materials and Manufacturing for Applications in new S-curve industries). 2022-11-02T02:54:19Z 2022-11-02T02:54:19Z 2022 Journal Article Jamshidian, M., Promoppatum, P., Ramamurty, U. & Jhon, M. H. (2022). Modulating fracture toughness through processing-mediated mesostructure in additively manufactured Al-12Si alloy. Materials and Design, 215, 110440-. https://dx.doi.org/10.1016/j.matdes.2022.110440 0261-3069 https://hdl.handle.net/10356/162655 10.1016/j.matdes.2022.110440 2-s2.0-85124480253 215 110440 en A18B1b0061 Materials and Design © 2022 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/). application/pdf |
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Engineering::Mechanical engineering Engineering::Materials Fracture Toughness Laser Powder Bed Fusion Jamshidian, Mostafa Promoppatum, Patcharapit Ramamurty, Upradrasta Jhon, Mark Hyunpong Modulating fracture toughness through processing-mediated mesostructure in additively manufactured Al-12Si alloy |
| description |
Al-12Si alloy processed through additive manufacturing exhibits a complex hierarchical structure. At the mesoscale, its melt pool boundaries constitute a network of weak interfaces that provides preferred pathways for crack kinking, leading to both marked anisotropy and apparent enhancement in the fracture energy. In this study, a multiscale cohesive zone-based computational model and a semi-analytical approach for kinked cracks are used to investigate the effect of melt pool configuration on fracture energy enhancement and anisotropy due to crack path tortuosity. We experimentally validate our methodology using fracture toughness testing of compact tension specimens, then systematically study the simultaneous effects of hatch spacing, layer thickness, and crack surface orientation on variations of the fracture energy. While the fracture energy increases with increasing hatch spacing and decreasing layer thickness, processing defects such as keyholing give practical limits to the melt pool geometry, limiting the fracture energy enhancement. We found that the fracture energy can be enhanced as high as a factor of two with an optimal crack surface orientation that is linearly proportional to the ratio of hatch spacing to layer thickness and varies between 60° and 100°. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Jamshidian, Mostafa Promoppatum, Patcharapit Ramamurty, Upradrasta Jhon, Mark Hyunpong |
| format |
Article |
| author |
Jamshidian, Mostafa Promoppatum, Patcharapit Ramamurty, Upradrasta Jhon, Mark Hyunpong |
| author_sort |
Jamshidian, Mostafa |
| title |
Modulating fracture toughness through processing-mediated mesostructure in additively manufactured Al-12Si alloy |
| title_short |
Modulating fracture toughness through processing-mediated mesostructure in additively manufactured Al-12Si alloy |
| title_full |
Modulating fracture toughness through processing-mediated mesostructure in additively manufactured Al-12Si alloy |
| title_fullStr |
Modulating fracture toughness through processing-mediated mesostructure in additively manufactured Al-12Si alloy |
| title_full_unstemmed |
Modulating fracture toughness through processing-mediated mesostructure in additively manufactured Al-12Si alloy |
| title_sort |
modulating fracture toughness through processing-mediated mesostructure in additively manufactured al-12si alloy |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/162655 |
| _version_ |
1749179140835115008 |