Programmable multistability for 3D printed reinforced multifunctional composites with reversible shape change
4D printing empowers 3D printed structures made of hydrogels, liquid crystals or shape memory polymers, with reversible morphing capabilities in response to an external stimulus. To apply reversible shape-change to stiff lightweight materials such as microfiber reinforced polymers, we developed a co...
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sg-ntu-dr.10356-1531132023-03-04T17:24:55Z Programmable multistability for 3D printed reinforced multifunctional composites with reversible shape change Puthanveetil, Shanthini Liu, Wing Chung Riley, Katherine S. Arrieta, Andres F. Le Ferrand, Hortense School of Mechanical and Aerospace Engineering School of Materials Science and Engineering Engineering::Materials::Composite materials Short-Fiber Composites Shape Memory Behaviou 4D printing empowers 3D printed structures made of hydrogels, liquid crystals or shape memory polymers, with reversible morphing capabilities in response to an external stimulus. To apply reversible shape-change to stiff lightweight materials such as microfiber reinforced polymers, we developed a composite ink that can be printed using direct-ink-writing (DIW), and that exhibits multistability around its glass transition temperature. After curing at room temperature, the flat print thermally morphs into a predefined shape upon heating at an actuation temperature and cooling down. The sample can then reversibly snap between multiple stable shapes when heated above its glass transition temperature thanks to pre-stress-induced multistability. The key that allows thermal morphing and pre-stress multistability is the microstructuring of the 3D printed composites by shear-induced alignment of reinforcing microfibers. This alignment leads to local anisotropy in thermomechanical properties and the build-up of pre-stresses. Furthermore, the ink composition can be tuned to generate shape-dependant reversible functional properties, such as electrical conductivity. Based on finite element modelling and experimental results, the method proposed here can be used for variety of compositions and designs, for applications where stiffness, reconfigurability and shape-dependent functionalities can be exploited. Ministry of Education (MOE) Accepted version The authors acknowledge financial support from the Ministry of Education, Singapore under Grant No. 2019-T1-001-002). This material is based upon work supported by the National Science Foundation Graduate Research Fellowship Program under Grant No. DGE-1333468. 2021-11-05T02:59:41Z 2021-11-05T02:59:41Z 2022 Journal Article Puthanveetil, S., Liu, W. C., Riley, K. S., Arrieta, A. F. & Le Ferrand, H. (2022). Programmable multistability for 3D printed reinforced multifunctional composites with reversible shape change. Composites Science and Technology, 217, 109097-. https://dx.doi.org/10.1016/j.compscitech.2021.109097 0266-3538 https://hdl.handle.net/10356/153113 10.1016/j.compscitech.2021.109097 217 109097 en 2019-T1-001-002 Composites Science and Technology © 2021 Elsevier Ltd. All rights reserved. This paper was published in Composites Science and Technology and is made available with permission of Elsevier Ltd. application/pdf |
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Engineering::Materials::Composite materials Short-Fiber Composites Shape Memory Behaviou Puthanveetil, Shanthini Liu, Wing Chung Riley, Katherine S. Arrieta, Andres F. Le Ferrand, Hortense Programmable multistability for 3D printed reinforced multifunctional composites with reversible shape change |
| description |
4D printing empowers 3D printed structures made of hydrogels, liquid crystals or shape memory polymers, with reversible morphing capabilities in response to an external stimulus. To apply reversible shape-change to stiff lightweight materials such as microfiber reinforced polymers, we developed a composite ink that can be printed using direct-ink-writing (DIW), and that exhibits multistability around its glass transition temperature. After curing at room temperature, the flat print thermally morphs into a predefined shape upon heating at an actuation temperature and cooling down. The sample can then reversibly snap between multiple stable shapes when heated above its glass transition temperature thanks to pre-stress-induced multistability. The key that allows thermal morphing and pre-stress multistability is the microstructuring of the 3D printed composites by shear-induced alignment of reinforcing microfibers. This alignment leads to local anisotropy in thermomechanical properties and the build-up of pre-stresses. Furthermore, the ink composition can be tuned to generate shape-dependant reversible functional properties, such as electrical conductivity. Based on finite element modelling and experimental results, the method proposed here can be used for variety of compositions and designs, for applications where stiffness, reconfigurability and shape-dependent functionalities can be exploited. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Puthanveetil, Shanthini Liu, Wing Chung Riley, Katherine S. Arrieta, Andres F. Le Ferrand, Hortense |
| format |
Article |
| author |
Puthanveetil, Shanthini Liu, Wing Chung Riley, Katherine S. Arrieta, Andres F. Le Ferrand, Hortense |
| author_sort |
Puthanveetil, Shanthini |
| title |
Programmable multistability for 3D printed reinforced multifunctional composites with reversible shape change |
| title_short |
Programmable multistability for 3D printed reinforced multifunctional composites with reversible shape change |
| title_full |
Programmable multistability for 3D printed reinforced multifunctional composites with reversible shape change |
| title_fullStr |
Programmable multistability for 3D printed reinforced multifunctional composites with reversible shape change |
| title_full_unstemmed |
Programmable multistability for 3D printed reinforced multifunctional composites with reversible shape change |
| title_sort |
programmable multistability for 3d printed reinforced multifunctional composites with reversible shape change |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/153113 |
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1759854705728552960 |