Mechanical properties of additively manufactured kraft paper lattices and paper-epoxy interpenetrating phase composites for polymer foam replacement
In an effort to reduce pollution by polymer wastes, cellulose paper is investigated as a polymer foam replacement for structural applications. Closed-cell plate lattices, open-cell truss lattices, honeycombs and epoxy-paper interpenetrating phase composites (IPC) were fabricated using a sheet lamina...
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sg-ntu-dr.10356-1730912024-01-13T16:48:31Z Mechanical properties of additively manufactured kraft paper lattices and paper-epoxy interpenetrating phase composites for polymer foam replacement Lim, Guo Yao Kuek, Ryan Jian Xing Teo, Javen Seetoh, Ian Peiyuan Lai, Chang Quan School of Mechanical and Aerospace Engineering School of Materials Science and Engineering Temasek Laboratories @ NTU Engineering::Mechanical engineering Kraft Paper Interpenetrating Phase Eomposite In an effort to reduce pollution by polymer wastes, cellulose paper is investigated as a polymer foam replacement for structural applications. Closed-cell plate lattices, open-cell truss lattices, honeycombs and epoxy-paper interpenetrating phase composites (IPC) were fabricated using a sheet lamination technique. The microstructures of both paper and IPC samples were examined using scanning electron microscopy and gas pycnometry. Modulus, strength and energy absorption of the structures were characterized with quasistatic compression test (strain rate = 0.2/s). To analyse the buckling behavior of different lattice geometries, finite element simulations were performed and the obtained results were validated with the captured deformation images. Under mechanical loading, it was observed that the lattices failed by kinking in the isostrain orientation while they generally failed by buckling in the isostress orientation. It was postulated that these failure modes minimized shear stresses between the sheets and were, therefore, preferred. Because the fibers were aligned to the load axis in the isostrain orientation, lattices were stiffer. Conversely, finite element simulations indicate that stresses were better distributed in the isostress orientation and hence, such lattices were stronger. The addition of epoxy matrix into an Octet Truss paper lattice increased its specific stiffness, specific strength and isotropy significantly. Other than acting as supports to reduce bending of the diagonal struts, epoxy was found to infiltrate into the space between kraft paper fibers, forming a fiber-reinforced composite that conferred an excellent bond to the paper lattice and epoxy. The paper-based structures were also found to collectively exhibit an energy absorption efficiency of 31 % (i.e. cushion factor ∼3), comparable to elastomeric polymer lattices. Further benchmarking against literature values indicate that the specific modulus, specific strength and volumetric energy absorption of the additively manufactured paper-based structures were either comparable or superior to most polymer foams, suggesting that such paper-based structures are viable green substitutes for polymer foams. Nanyang Technological University Submitted/Accepted version This work was partially supported by C.Q.L’s startup grant (award no.: 020868–00001). 2024-01-11T06:34:43Z 2024-01-11T06:34:43Z 2023 Journal Article Lim, G. Y., Kuek, R. J. X., Teo, J., Seetoh, I. P. & Lai, C. Q. (2023). Mechanical properties of additively manufactured kraft paper lattices and paper-epoxy interpenetrating phase composites for polymer foam replacement. Additive Manufacturing, 77, 103816-. https://dx.doi.org/10.1016/j.addma.2023.103816 2214-7810 https://hdl.handle.net/10356/173091 10.1016/j.addma.2023.103816 2-s2.0-85174325023 77 103816 en NTU-SUG (020868–00001) Additive Manufacturing © 2023 Elsevier B.V. All rights reserved. This article may be downloaded for personal use only. Any other use requires prior permission of the copyright holder. The Version of Record is available online at http://doi.org/10.1016/j.addma.2023.103816. application/pdf |
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Engineering::Mechanical engineering Kraft Paper Interpenetrating Phase Eomposite Lim, Guo Yao Kuek, Ryan Jian Xing Teo, Javen Seetoh, Ian Peiyuan Lai, Chang Quan Mechanical properties of additively manufactured kraft paper lattices and paper-epoxy interpenetrating phase composites for polymer foam replacement |
| description |
In an effort to reduce pollution by polymer wastes, cellulose paper is investigated as a polymer foam replacement for structural applications. Closed-cell plate lattices, open-cell truss lattices, honeycombs and epoxy-paper interpenetrating phase composites (IPC) were fabricated using a sheet lamination technique. The microstructures of both paper and IPC samples were examined using scanning electron microscopy and gas pycnometry. Modulus, strength and energy absorption of the structures were characterized with quasistatic compression test (strain rate = 0.2/s). To analyse the buckling behavior of different lattice geometries, finite element simulations were performed and the obtained results were validated with the captured deformation images. Under mechanical loading, it was observed that the lattices failed by kinking in the isostrain orientation while they generally failed by buckling in the isostress orientation. It was postulated that these failure modes minimized shear stresses between the sheets and were, therefore, preferred. Because the fibers were aligned to the load axis in the isostrain orientation, lattices were stiffer. Conversely, finite element simulations indicate that stresses were better distributed in the isostress orientation and hence, such lattices were stronger. The addition of epoxy matrix into an Octet Truss paper lattice increased its specific stiffness, specific strength and isotropy significantly. Other than acting as supports to reduce bending of the diagonal struts, epoxy was found to infiltrate into the space between kraft paper fibers, forming a fiber-reinforced composite that conferred an excellent bond to the paper lattice and epoxy. The paper-based structures were also found to collectively exhibit an energy absorption efficiency of 31 % (i.e. cushion factor ∼3), comparable to elastomeric polymer lattices. Further benchmarking against literature values indicate that the specific modulus, specific strength and volumetric energy absorption of the additively manufactured paper-based structures were either comparable or superior to most polymer foams, suggesting that such paper-based structures are viable green substitutes for polymer foams. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Lim, Guo Yao Kuek, Ryan Jian Xing Teo, Javen Seetoh, Ian Peiyuan Lai, Chang Quan |
| format |
Article |
| author |
Lim, Guo Yao Kuek, Ryan Jian Xing Teo, Javen Seetoh, Ian Peiyuan Lai, Chang Quan |
| author_sort |
Lim, Guo Yao |
| title |
Mechanical properties of additively manufactured kraft paper lattices and paper-epoxy interpenetrating phase composites for polymer foam replacement |
| title_short |
Mechanical properties of additively manufactured kraft paper lattices and paper-epoxy interpenetrating phase composites for polymer foam replacement |
| title_full |
Mechanical properties of additively manufactured kraft paper lattices and paper-epoxy interpenetrating phase composites for polymer foam replacement |
| title_fullStr |
Mechanical properties of additively manufactured kraft paper lattices and paper-epoxy interpenetrating phase composites for polymer foam replacement |
| title_full_unstemmed |
Mechanical properties of additively manufactured kraft paper lattices and paper-epoxy interpenetrating phase composites for polymer foam replacement |
| title_sort |
mechanical properties of additively manufactured kraft paper lattices and paper-epoxy interpenetrating phase composites for polymer foam replacement |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/173091 |
| _version_ |
1789483183645917184 |