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Cactus-inspired design principles for soft robotics based on 3D printed hydrogel-elastomer systems

Anil Bastola, Nadia Rodriguez, Marc Behl, Patricia Soffiatti, Nick P. Rowe, Andreas Lendlein

Materials and Design, Volume: 202, Start page: 109515

Swansea University Author: Anil Bastola

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DOI (Published version): 10.1016/j.matdes.2021.109515

Abstract

Plants have evolved many capabilities to anchor, position their stems and leaves favourably, and adapt themselves to different environmental conditions by virtue of growing. Selenicereus setaceus is a cactus and is an impressive example of a climbing plant found mostly in the Atlantic forest formati...

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Published in: Materials and Design
ISSN: 0264-1275
Published: Elsevier BV 2021
Online Access: Check full text

URI: https://cronfa.swan.ac.uk/Record/cronfa65754
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Abstract: Plants have evolved many capabilities to anchor, position their stems and leaves favourably, and adapt themselves to different environmental conditions by virtue of growing. Selenicereus setaceus is a cactus and is an impressive example of a climbing plant found mostly in the Atlantic forest formations of southern Brazil. This cactus displays striking changes in stem geometry along different stages of growth: older parts are circular while the younger parts are star-like in shape. Such a transformation in shape optimizes its flexural rigidity and allows the cactus to search in three-dimensionally complex environments. Its organisation offers novel schemes for the design of plant-inspired soft robotic systems. In this paper, we have created multi-material systems for soft robotics that display controlled movements as well as mimicking the cactus stem geometries from star-like to circular. The unique star-shaped geometry is 3D printed using a soft elastomer and hydrogel is used as an actuating component. Through anisotropic swelling, the hydrogel-elastomer system adjusts its configuration and shows a controlled movement. Furthermore, the isotropic swelling of the hydrogel of the artificial cactus multi-material system result in the change in shape from star-like to circular as the cactus does naturally in the tropical forest.
Keywords: Cactus-inspired; Hydrogel-elastomer; Multi-material; 3D printing; Soft-robotics
College: Faculty of Science and Engineering
Funders: Mrs. Yvonne Pieper is acknowledged for cross-sectional images of the artificial cactus. This work was financially supported by the Helmholtz Association through programme-oriented funding and received funding from the European Union's Horizon 2020 research and innovation program under Grant Agreement No. 824074 (GrowBot).
Start Page: 109515

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