3D printing of ceramic microlattices and derived composites
Mechanical properties of 3D printed ceramics with structural advantage were investigated. Three structures were studied namely, Kelvin Cell (bending dominated), Octet Truss (stretching dominated) and Simple Cubic lattice (stretching dominated). The structures were 3D printed using the stereolitho...
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2020
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sg-ntu-dr.10356-1437272023-03-04T16:41:47Z 3D printing of ceramic microlattices and derived composites Yap, Xiu Yun Gan Chee Lip School of Materials Science and Engineering CLGan@ntu.edu.sg Engineering::Materials Mechanical properties of 3D printed ceramics with structural advantage were investigated. Three structures were studied namely, Kelvin Cell (bending dominated), Octet Truss (stretching dominated) and Simple Cubic lattice (stretching dominated). The structures were 3D printed using the stereolithography method at different relative densities of alumina. Across the lattices, as the relative density is increased, the compressive strength, Young’s modulus and energy absorption also increased. The ceramic lattices have higher compressive strength and stiffness, but lower strain and energy absorption compared to ductile lattices made of polymer or metal. Simple Cubic lattices have the best performance because of its vertically aligned struts that underwent mostly compressive forces. The inclined struts in Kelvin Cells and Octet Truss lattices induce higher tensile stresses in the joints, which does not work well for ceramic materials. Unlike ductile lattices, ceramic lattices undergo brittle fracture and have minimum densification phenomenon. The low relative density Kelvin Cells and Octet Truss lattices exhibit pseudoplastic behavior which would give users time to react before a catastrophic failure occurs. Another study was done on the mechanical properties of Octet Truss EpoxyAlumina Interpenetrating Phase Composite (IPC). Fabrication process for IPC was established in the study. The secondary phase provides support to the lattice and prevents catastrophic failure of Octet Truss IPC, resulting in improved specific compressive strength, strain and energy absorption. Such IPCs could potentially fill the gap for stronger structures that have higher ductility to provide better energy absorption properties per unit weight. This could be utilized in light weight shock absorption applications such as body armour and crash barriers. Master of Engineering 2020-09-21T04:20:42Z 2020-09-21T04:20:42Z 2020 Thesis-Master by Research Yap, X. Y (2020). 3D printing of ceramic microlattices and derived composites. Master's thesis, Nanyang Technological University, Singapore. https://hdl.handle.net/10356/143727 10.32657/10356/143727 en This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License (CC BY-NC 4.0). application/pdf Nanyang Technological University |
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Engineering::Materials Yap, Xiu Yun 3D printing of ceramic microlattices and derived composites |
| description |
Mechanical properties of 3D printed ceramics with structural advantage were
investigated. Three structures were studied namely, Kelvin Cell (bending dominated),
Octet Truss (stretching dominated) and Simple Cubic lattice (stretching
dominated). The structures were 3D printed using the stereolithography method at
different relative densities of alumina.
Across the lattices, as the relative density is increased, the compressive strength,
Young’s modulus and energy absorption also increased. The ceramic lattices have
higher compressive strength and stiffness, but lower strain and energy absorption
compared to ductile lattices made of polymer or metal. Simple Cubic lattices have the
best performance because of its vertically aligned struts that underwent mostly
compressive forces. The inclined struts in Kelvin Cells and Octet Truss lattices induce
higher tensile stresses in the joints, which does not work well for ceramic materials.
Unlike ductile lattices, ceramic lattices undergo brittle fracture and have minimum
densification phenomenon. The low relative density Kelvin Cells and Octet Truss
lattices exhibit pseudoplastic behavior which would give users time to react before a
catastrophic failure occurs.
Another study was done on the mechanical properties of Octet Truss EpoxyAlumina Interpenetrating Phase Composite (IPC). Fabrication process for IPC was
established in the study. The secondary phase provides support to the lattice and
prevents catastrophic failure of Octet Truss IPC, resulting in improved specific
compressive strength, strain and energy absorption. Such IPCs could potentially fill the
gap for stronger structures that have higher ductility to provide better energy absorption
properties per unit weight. This could be utilized in light weight shock absorption
applications such as body armour and crash barriers. |
| author2 |
Gan Chee Lip |
| author_facet |
Gan Chee Lip Yap, Xiu Yun |
| format |
Thesis-Master by Research |
| author |
Yap, Xiu Yun |
| author_sort |
Yap, Xiu Yun |
| title |
3D printing of ceramic microlattices and derived composites |
| title_short |
3D printing of ceramic microlattices and derived composites |
| title_full |
3D printing of ceramic microlattices and derived composites |
| title_fullStr |
3D printing of ceramic microlattices and derived composites |
| title_full_unstemmed |
3D printing of ceramic microlattices and derived composites |
| title_sort |
3d printing of ceramic microlattices and derived composites |
| publisher |
Nanyang Technological University |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/143727 |
| _version_ |
1759854400523730944 |