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Hauptverfasser: Huang, Hongbin, Lin, Zhonglu, Zheng, Wei, Zhang, Jinhu, Liu, Zhibin, Zhou, Wei, Zhang, Yu
Format: Preprint
Veröffentlicht: 2024
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2407.18843
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author Huang, Hongbin
Lin, Zhonglu
Zheng, Wei
Zhang, Jinhu
Liu, Zhibin
Zhou, Wei
Zhang, Yu
author_facet Huang, Hongbin
Lin, Zhonglu
Zheng, Wei
Zhang, Jinhu
Liu, Zhibin
Zhou, Wei
Zhang, Yu
contents Median fins of fish-like swimmers play a crucial role in linear acceleration and maneuvering processes. However, few research focused on untethered robotic fish experiments. Imitating the behaviour of real tuna, we developed a free-swimming bionic tuna with a foldable dorsal fin. The erection of dorsal fin, at proper conditions, can reduce head heave by 50%, enhance linear acceleration by 15.7%, increase turning angular velocity by 32.78%, and turning radius decreasing by 33.13%. Conversely, erecting the dorsal fin increases the wetted surface area, resulting in decreased maximum speed and efficiency during steady swimming phase. This finding partially explains why tuna erect their median fins during maneuvers or acceleration and fold them afterward to reduce drag. In addition, we verified that folding the median fins after acceleration does not significantly affect locomotion efficiency. This study supports the application of morphing median fins in undulating underwater robots and helps to further understand the impact of median fins on fish locomotion.
format Preprint
id arxiv_https___arxiv_org_abs_2407_18843
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Morphing median fin enhances untethered bionic robotic tuna's linear acceleration and turning maneuverability
Huang, Hongbin
Lin, Zhonglu
Zheng, Wei
Zhang, Jinhu
Liu, Zhibin
Zhou, Wei
Zhang, Yu
Robotics
Biological Physics
Fluid Dynamics
Median fins of fish-like swimmers play a crucial role in linear acceleration and maneuvering processes. However, few research focused on untethered robotic fish experiments. Imitating the behaviour of real tuna, we developed a free-swimming bionic tuna with a foldable dorsal fin. The erection of dorsal fin, at proper conditions, can reduce head heave by 50%, enhance linear acceleration by 15.7%, increase turning angular velocity by 32.78%, and turning radius decreasing by 33.13%. Conversely, erecting the dorsal fin increases the wetted surface area, resulting in decreased maximum speed and efficiency during steady swimming phase. This finding partially explains why tuna erect their median fins during maneuvers or acceleration and fold them afterward to reduce drag. In addition, we verified that folding the median fins after acceleration does not significantly affect locomotion efficiency. This study supports the application of morphing median fins in undulating underwater robots and helps to further understand the impact of median fins on fish locomotion.
title Morphing median fin enhances untethered bionic robotic tuna's linear acceleration and turning maneuverability
topic Robotics
Biological Physics
Fluid Dynamics
url https://arxiv.org/abs/2407.18843