Investigation on the mechanical behaviour of 3-D printed lattice sandwich structures
Cellular lattice structures have been gaining traction because of its fairly low mass and density, high stiffness, decent energy absorption capabilities and thermal and acoustic insulation. These unique characteristics and multifunctional advantages have enabled lattice structures to be preferred...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
2016
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| Subjects: | |
| Online Access: | http://hdl.handle.net/10356/68389 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Cellular lattice structures have been gaining traction because of its fairly low mass and density,
high stiffness, decent energy absorption capabilities and thermal and acoustic insulation. These
unique characteristics and multifunctional advantages have enabled lattice structures to be
preferred as the cores of sandwich panels over its counterparts such as foams and
honeycombs, and significantly amplified their usage in engineering applications for a variety of
fields, such as automobile, aerospace and bioengineering. A number of manufacturing methods
are capable of fabricating cellular lattice structures. However, recent advancements in additive
manufacturing have allowed for the fabrication of sophisticated designs and geometries of
cellular lattice structures to a significantly high level of accuracy. This paper focuses on the
comparison of mechanical properties of two 3-D printed cellular lattice structures, the Body-
Centered-Cubic (BCC) and the 3-D Kagome. The selected lattice structures were designed in
two configurations each to study on the effect of relative density on mechanical properties. Six
specimens per design configuration (total of 24) were fabricated using the Projet 5500X 3-D
Printer. Tensile test was conducted to evaluate the Young’s Modulus of the composite material,
and compression test was conducted to determine the compressive response of each
configuration. Both the ultimate compressive strength and compressive modulus of each
configuration were normalized with the average mass of the specimens to improve accuracy,
and the normalized data was analyzed. The 3-D Kagome was found to be a stiffer structure,
whereas the BCC was found to exhibit better energy absorption characteristics. The findings
concluded from this paper aim to create a better understanding of the selected cellular lattice
structures, and also provide recommendations for future work on 3-D printed cellular lattice
structures. |
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