RETRACTED: An eel-like robot based on a dielectric elastomer
Chenghong Zhang

TL;DR
Researchers designed an eel-like robot using dielectric elastomers, which can swim efficiently and maneuverably in water.
Contribution
A novel eel-inspired robot using dielectric elastomers is developed with a focus on biomimetic motion and improved manufacturability.
Findings
The robot can perform an S-type angle swinging motion.
A kinematic model was established to analyze propulsion speed and swimming shape.
The design improves energy efficiency and maneuverability in narrow spaces.
Abstract
Eels have attracted significant research interest because of their long-distance migration and high-endurance cruising behavior. An underwater eel-like robot design inspired by these creatures has the potential for high efficiency, strong maneuverability and high stability. The propulsive biomimetic eel-like robot has the lowest energy consumption per unit distance, and its flexible body is conducive to movement and operation in narrow spaces; this is expected to become the research and development direction for underwater biomimetic robots. Dielectric elastomers (DEs) are smart, soft materials that exhibit significant deformation under an electric field and have the characteristics of large strain, fast response, light mass, etc. Applying DEs in the effort to develop bionic robots affords a unique advantage. This study introduces an eel-inspired swimming robot. First, a cylindrical…
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Taxonomy
TopicsDielectric materials and actuators · Advanced Sensor and Energy Harvesting Materials · Soft Robotics and Applications
