4.7 Article

Multimaterial direct 4D printing of high stiffness structures with large bending curvature

Journal

EXTREME MECHANICS LETTERS
Volume 42, Issue -, Pages -

Publisher

ELSEVIER
DOI: 10.1016/j.eml.2020.101122

Keywords

4D printing; Multimaterial; High stiffness; Large bending curvature; Dehydration

Funding

  1. Key-Area Research and Development Program of Guangdong Province, China [2020B090923003]
  2. Centers for Mechanical Engineering Research and Education at MIT, US
  3. SUSTech, China
  4. SUTD Digital Manufacturing and Design Centre (DManD) - Singapore National Research Foundation [RGDM1830206, RGDM1710205, RGDM1830501]
  5. National Natural Science Foundation of China [11802233]

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The emerging direct four dimensional (4D) printing approach allows for the fabrication of complex 3D geometries from printed flat patterns, but faces challenges in achieving both large bending curvature and high loading capacity simultaneously. A multimaterial direct 4D printing method has been developed to address this issue, utilizing dehydration induced shrinkage and stiffening to create 3D structures with large bending curvature and high bending stiffness. This approach demonstrates advantages in terms of less building time and high load capacity compared to other 3D printing technologies.
The emerging direct four dimensional (4D) printing approach is considered as an easy, fast and economical manufacturing strategy that fabricates complex 3D geometries evolving from printed flat patterns in response to external stimuli. However, its implementation to practical engineering applications is impeded by the fact that the existing direct 4D printing methods could not render both the large bending curvature and high loading capacity at the same time. Herein, we report a multimaterial direct 4D printing method to fabricate patterned laminate that consists of covalently bonded elastomer and high-water-content hydrogel. The dehydration induced large volumetric shrinkage (up to 60%) and great modulus escalation (from 100 kPa to 4 GPa) allow the printed flat patterns to evolve into complex 3D structures with large bending curvature (up to 0.7 mm-1) and high bending stiffness (up to 104 MPa m(3)). To facilitate the structural design, we develop a phenomenological model to describe the dehydration induced shrinkage and stiffening, and implement this model into Euler-Bernoulli beam theory and finite element simulations. Compared with other 3D printing technologies, the proposed multimaterial direct 4D printing approach demonstrates the merits in terms of less building time and high load capacity at both room temperature and high temperature. (C) 2020 Elsevier Ltd. All rights reserved.

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