4D printing of heat-driven self-assembly structures (Part II)
Due to multi-material 3D printing technology developed in recent times, the new concept of 4D printing has emerged. In 4D printing, besides the regular three dimensions, the fourth dimension is time-dependent shape change of the printed product. This allows models to be printed in a specific form an...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
2015
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| Online Access: | http://hdl.handle.net/10356/64951 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Due to multi-material 3D printing technology developed in recent times, the new concept of 4D printing has emerged. In 4D printing, besides the regular three dimensions, the fourth dimension is time-dependent shape change of the printed product. This allows models to be printed in a specific form and activated by external stimulus to change its shape in a controlled method, hence opening the possibility of self-assembled structures. This creates a myriad of applications in situations where manual assembly of a structure is neither favoured nor possible. This project investigates and develops devices that facilitate the design and modeling of multistage folding process in self-assembling 4D printed structures with heat-driven shape memory polymers. First, the fabrication conditions of heat-driven self-assembly structures are examined. Hinges are printed with varying materials and dimensional parameters, and the resulting recovery time and the angle integrity are analysed. Next, two multi-stage folding techniques – insulating overlay and localized material variation are developed and tested. Finally, using the most effective multi-stage technique – localized material variation, an origami glider is designed to demonstrate the multi-stage folding in application. |
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