Enhanced mechanical and thermal properties in 3D printed Al2O3 lattice/epoxy interpenetrating phase composites

Interpenetrating phase composites (IPCs) with 3D printed alumina microlattices infiltrated with epoxy have been fabricated. Mechanical analysis shows that the IPCs under quasi-static compression generally exhibit fracture behaviour similar to that of their ceramic-lattice constituent but in a gradua...

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Main Authors: Zhao, Yida, Yap, Xiu Yun, Ye, Pengcheng, Seetoh, Ian, Guo, Huilu, Lai, Changquan, Du, Zehui, Gan, Chee Lip
Other Authors: School of Mechanical and Aerospace Engineering
Format: Article
Language:English
Published: 2024
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Online Access:https://hdl.handle.net/10356/177949
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-1779492024-06-03T06:43:25Z Enhanced mechanical and thermal properties in 3D printed Al2O3 lattice/epoxy interpenetrating phase composites Zhao, Yida Yap, Xiu Yun Ye, Pengcheng Seetoh, Ian Guo, Huilu Lai, Changquan Du, Zehui Gan, Chee Lip School of Mechanical and Aerospace Engineering School of Materials Science and Engineering Temasek Laboratories @ NTU Engineering Interpenetrating phase composites Alumina lattice Interpenetrating phase composites (IPCs) with 3D printed alumina microlattices infiltrated with epoxy have been fabricated. Mechanical analysis shows that the IPCs under quasi-static compression generally exhibit fracture behaviour similar to that of their ceramic-lattice constituent but in a gradual manner. The IPCs with Simple Cubic lattices initiate the fractures at the struts in the outer lattice planes, while IPCs with Octet Truss and Kelvin Cell lattices tend to fracture at their (110) or (111) planes. The compressive strength and energy absorption of IPCs follow the order of Simple Cubic > Kelvin Cells > Octet Truss when the ceramic volume fraction is 0.3. The IPCs display compressive strengths up to 120% higher and energy absorption 100% greater than the iso-strain combined properties of the lattice and epoxy. The factors governing the fracture behaviour and the strengthening and energy absorption mechanisms are thoroughly discussed. Furthermore, the IPCs show much better retention of mechanical strength and dimensional stability at elevated temperatures compared with many commonly used particle or fiber-reinforced epoxy matrix composites. 2024-06-03T06:43:25Z 2024-06-03T06:43:25Z 2024 Journal Article Zhao, Y., Yap, X. Y., Ye, P., Seetoh, I., Guo, H., Lai, C., Du, Z. & Gan, C. L. (2024). Enhanced mechanical and thermal properties in 3D printed Al2O3 lattice/epoxy interpenetrating phase composites. Mechanics of Materials, 190, 104930-. https://dx.doi.org/10.1016/j.mechmat.2024.104930 0167-6636 https://hdl.handle.net/10356/177949 10.1016/j.mechmat.2024.104930 2-s2.0-85183922723 190 104930 en Mechanics of Materials © 2024 Elsevier Ltd. All rights reserved.
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic Engineering
Interpenetrating phase composites
Alumina lattice
spellingShingle Engineering
Interpenetrating phase composites
Alumina lattice
Zhao, Yida
Yap, Xiu Yun
Ye, Pengcheng
Seetoh, Ian
Guo, Huilu
Lai, Changquan
Du, Zehui
Gan, Chee Lip
Enhanced mechanical and thermal properties in 3D printed Al2O3 lattice/epoxy interpenetrating phase composites
description Interpenetrating phase composites (IPCs) with 3D printed alumina microlattices infiltrated with epoxy have been fabricated. Mechanical analysis shows that the IPCs under quasi-static compression generally exhibit fracture behaviour similar to that of their ceramic-lattice constituent but in a gradual manner. The IPCs with Simple Cubic lattices initiate the fractures at the struts in the outer lattice planes, while IPCs with Octet Truss and Kelvin Cell lattices tend to fracture at their (110) or (111) planes. The compressive strength and energy absorption of IPCs follow the order of Simple Cubic > Kelvin Cells > Octet Truss when the ceramic volume fraction is 0.3. The IPCs display compressive strengths up to 120% higher and energy absorption 100% greater than the iso-strain combined properties of the lattice and epoxy. The factors governing the fracture behaviour and the strengthening and energy absorption mechanisms are thoroughly discussed. Furthermore, the IPCs show much better retention of mechanical strength and dimensional stability at elevated temperatures compared with many commonly used particle or fiber-reinforced epoxy matrix composites.
author2 School of Mechanical and Aerospace Engineering
author_facet School of Mechanical and Aerospace Engineering
Zhao, Yida
Yap, Xiu Yun
Ye, Pengcheng
Seetoh, Ian
Guo, Huilu
Lai, Changquan
Du, Zehui
Gan, Chee Lip
format Article
author Zhao, Yida
Yap, Xiu Yun
Ye, Pengcheng
Seetoh, Ian
Guo, Huilu
Lai, Changquan
Du, Zehui
Gan, Chee Lip
author_sort Zhao, Yida
title Enhanced mechanical and thermal properties in 3D printed Al2O3 lattice/epoxy interpenetrating phase composites
title_short Enhanced mechanical and thermal properties in 3D printed Al2O3 lattice/epoxy interpenetrating phase composites
title_full Enhanced mechanical and thermal properties in 3D printed Al2O3 lattice/epoxy interpenetrating phase composites
title_fullStr Enhanced mechanical and thermal properties in 3D printed Al2O3 lattice/epoxy interpenetrating phase composites
title_full_unstemmed Enhanced mechanical and thermal properties in 3D printed Al2O3 lattice/epoxy interpenetrating phase composites
title_sort enhanced mechanical and thermal properties in 3d printed al2o3 lattice/epoxy interpenetrating phase composites
publishDate 2024
url https://hdl.handle.net/10356/177949
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