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Abstract Snap‐through bistability is often observed in nature (e.g., fast snapping to closure of Venus flytrap) and the life (e.g., bottle caps and hair clippers). Recently, harnessing bistability and multistability in different structures and soft materials has attracted growing interest for high‐performance soft actuators and soft robots. They have demonstrated broad and unique applications in high‐speed locomotion on land and under water, adaptive sensing and fast grasping, shape reconfiguration, electronics‐free controls with a single input, and logic computation. Here, an overview of integrating bistable and multistable structures with soft actuating materials for diverse soft actuators and soft/flexible robots is given. The mechanics‐guided structural design principles for five categories of basic bistable elements from 1D to 3D (i.e., constrained beams, curved plates, dome shells, compliant mechanisms of linkages with flexible hinges and deformable origami, and balloon structures) are first presented, alongside brief discussions of typical soft actuating materials (i.e., fluidic elastomers and stimuli‐responsive materials such as electro‐, photo‐, thermo‐, magnetic‐, and hydro‐responsive polymers). Following that, integrating these soft materials with each category of bistable elements for soft bistable and multistable actuators and their diverse robotic applications are discussed. To conclude, perspectives on the challenges and opportunities in this emerging field are considered.
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Development, Modeling, and Testing of a Passive Compliant Bistable Undulatory Robot
This proposed device uses a single actuator to transition a bistable constrained compliant beam to generate undulatory motion. Undulatory locomotion is a unique form of swimming that generates thrust through the propagation of a wave through a fish’s body. This paper draws inspiration from Anguilliformes and discusses the kinematics and dynamics of wave propagation of a bistable underwater robot. Thrust generation is explored through modeling and experimentation of the length constraint to better understand the device. This paper validates the theoretical spine behavior through experimentation and provides a path forward for future development in device optimization for various applications. Previous work developed devices that utilized either paired soft actuators or multiple redundant classical actuators that resulted in a complex prototype with intricate controls. Our work contrasts with prior work in that it aims to achieve undulatory motion through passive actuation from a single actively driven point which simplifies the control. Through this work, the goal is to further explore low-cost soft robotics via bistable mechanisms, continuum material properties, and simplified modeling practices.
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- Award ID(s):
- 1935324
- PAR ID:
- 10465706
- Editor(s):
- Meder, F.
- Date Published:
- Journal Name:
- Biomimetic and Biohybrid Systems. Living Machines 2023. Lecture Notes in Computer Science
- Volume:
- 14157
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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