Multimodal Soft Amphibious Robots Using Simple Plastic-Sheet-Reinforced Thin Pneumatic Actuators
Jiaxi Wu, Mingxin Wu, Wenhui Chen, Chen Wang, Guangming Xie
- Year
- 2024
- Citations
- 31
Abstract
A large challenge in the field of soft amphibious robotics is achieving high maneuverability and multi-terrain adaptability through multi-modal locomotion in hybrid terrestrial-aquatic environments. To address this issue, drawing inspiration from fruit-fly larvae and Spanish dancer sea slugs, a novel tethered soft amphibious robot with multi-modal locomotion is proposed in this paper, performing forward, backward, turning, and self-overturn motions both on land and in water. It leverages plastic sheet-reinforced thin pneumatic actuators, which are constructed from thermoplastic membranes and embedded with a non-stretchable plastic sheet, enabling bi-directional bending with large angles. The robot achieves a forward jumping velocity of 1.77BL/s and a forward swimming velocity of 0.69BL/s, both faster than previously reported soft amphibious robots; connecting two actuator units in parallel, it achieves agile turning with a velocity of 111.8 <inline-formula xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink"><tex-math notation="LaTeX">$^\circ$</tex-math></inline-formula> /s. Our proposed robot demonstrates exceptional multi-terrain adaptability, facile terrestrial-aquatic transition capabilities, and underwater buoyancy adjustment ability. Especially when accidentally overturned, it can recover itself without external assistance, a capability rarely achieved by other soft robots.
Keywords
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