Design and Analysis for a Diving‐Beetle‐Inspired Swimming Robot with Multi‐Flexible Appendages

Design and Analysis for a Diving‐Beetle‐Inspired Swimming Robot with Multi‐Flexible Appendages

In nature, the diving beetle is a drag‐powered excellent swimmer. It uses the flexible multi‐segment appendages to generate asymmetric force during the power stroke and recovery stroke for swimming. Meanwhile, the middle appendages are considered to help regulate stability. Inspired by this, a compr...

Full description

Saved in:
Bibliographic Details
Main Authors: Xinyi Gao, Zhenlin Jin, Lin Liang, Zhipeng Hu, Kai He, Fengran Xie, Qiyang Zuo
Format: Article
Language:English
Published: Wiley 2025-07-01
Series:Advanced Intelligent Systems
Subjects:
bionic underwater robots
compliant passive joints
middle appendages
motion controls
Online Access:https://doi.org/10.1002/aisy.202400820
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:In nature, the diving beetle is a drag‐powered excellent swimmer. It uses the flexible multi‐segment appendages to generate asymmetric force during the power stroke and recovery stroke for swimming. Meanwhile, the middle appendages are considered to help regulate stability. Inspired by this, a comprehensive study on a diving‐beetle‐like swimming robot is presented. The design of the robot is first demonstrated. Soft rubber is used as a passive flexible joint for the multi‐flexible appendage, and the swimming gaits are mimicked. Next, to validate the effectiveness of the proposed appendage design, its dynamic model is established and the effects of overly high and overly low stiffness on net thrust generation are compared. Finally, extensive thrust and swimming tests are conducted. The experimental results show that by mimicking the diving beetle's appendage structure and swimming gaits, the proposed robot can effectively perform forward swimming and turning maneuvers. Furthermore, comparing only the hind appendage, the experimental results reveal that coordinating the hind appendage and the middle appendage gives the robot a faster turning speed. Additionally, utilizing the enhanced maneuverability, a proportional‐derivative controller is employed to control the robot's yaw stability, and the experimental results demonstrate that the robot has good robustness and disturbance resistance.
ISSN:2640-4567

Similar Items