Research on the Undulatory Motion Mechanism of Seahorse Based on Dynamic Mesh

Quan, Xinyu; Zhao, Ximing; Zhang, Shijie; Zhou, Jie; Yu, Nan; Hou, Xuyan

doi:10.1155/2021/2807236

Cited by 4 publications

(1 citation statement)

References 14 publications

(13 reference statements)

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“…The low-speed maneuverability and hovering performance of undulatory fin propulsion are very inline with the current needs of ocean engineering for operation in complex environment. Therefore, research institutions such as Northwestern University and Nanyang University of Technology have studied various organisms which swim by means of an undulating fin, such as manta ray [9][10][11], stingray [12], black ghost knifefish [13,14], Rhinoptera javanica [15], and seahorse [16]. The various approaches they employed encompass analysis of kinematic data from live swimming fish [17], computational fluid dynamics (CFD) studies [13,18,19], and theoretical modeling [4,20,21].…”

Section: Introductionmentioning

confidence: 99%

Inspired by the Black Ghost Knifefish: Bionic Design of Undulatory Fin with 2-DOF Rays and Its Propulsion Performance

Zhou

Liu

et al. 2023

Applied Bionics and Biomechanics

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The demand for high-performance underwater thrusters in marine engineering is increasing. The concealed, mobile, and efficient underwater ability of fish provides many directions for research. The black ghost knifefish uses only wavy ventral fins to swim and can hover and roll in the water. Based on the physiological and morphological characteristics of the black ghost knifefish, we explored the structure and movement mode of the ventral fin, so as to establish a two-degree of freedom (2-DOF) structural model and kinematic model. We reveal the motion mechanism of the undulating fin propulsion through the constructed model and computational fluid dynamics. It is found that when the fin surface fluctuates, a pair of vortices with opposite directions will be formed on the concave side of the fin surface. These vortices will produce a central jet on the fin surface, provide a reverse impulse for the ventral fin, and make the fin obtain power. In addition, we found that the propulsive force of the ribbon fin along the body direction is positively correlated with the swing amplitude and frequency of the fin movement, and the propulsive torque of the ribbon fin to realize the maneuvering movement increases first and then decreases with the increase of the torsion angle. The research on the structure and motion mechanism of the ribbon fin of the black ghost knifefish provides a basis for the development of a bionic prototype of multi-DOF motion and the control strategy of high-mobility motion.

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Section: Introductionmentioning

confidence: 99%

Inspired by the Black Ghost Knifefish: Bionic Design of Undulatory Fin with 2-DOF Rays and Its Propulsion Performance

Zhou

Liu

et al. 2023

Applied Bionics and Biomechanics

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A comparison for hydrodynamic performance of undulating fin propulsion on numerical self-propulsion and tethered models

Chang

Shi

et al. 2022

Ocean Engineering

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Hydrodynamic performance analysis of undulating fin propulsion

Wei,

Hu,

et al. 2023

Physics of Fluids

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A desire to further comprehend the hydrodynamic characteristics of three-dimensional undulating fin propulsion is what motivates the work. First, a high-resolution numerical technique based on the constraint immersed boundary method is utilized to simulate the fluid-fin system. The simulation results reveal fundamental variation laws between the hydrodynamic performance of the undulating fin and kinematic parameters. According to the simulation data, an in-depth analysis of the scaling law is conducted. A key contribution of this work is to build the force scaling formula and extend the law to complicated cases involving different incoming flow velocities. The important application of the force scaling law is that it can be used to estimate the self-propelled speed and wave efficiency of the undulating fin in different kinematic conditions. The results show that the wave efficiency exhibits a monotonically bounded increasing trend as the amplitude grows, is basically independent of the frequency, and decreases monotonically with the increasing wavelength. Finally, the work discusses the evolution of vortex structures in undulating fin propulsion. The analysis indicates that the streamwise central jet formed throughout the fin body is the primary reason for thrust generation in undulating fin propulsion. Furthermore, the basic dynamic mechanisms of two types of vortex rings, related to the formation of the central jet, are investigated in the work. The results further reveal the macro-interaction mechanism between the undulating fin and fluid flow. The findings could make a contribution to explaining some biological phenomena and developing bionic engineering.

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Research on the Undulatory Motion Mechanism of Seahorse Based on Dynamic Mesh

Cited by 4 publications

References 14 publications

Inspired by the Black Ghost Knifefish: Bionic Design of Undulatory Fin with 2-DOF Rays and Its Propulsion Performance

Inspired by the Black Ghost Knifefish: Bionic Design of Undulatory Fin with 2-DOF Rays and Its Propulsion Performance

A comparison for hydrodynamic performance of undulating fin propulsion on numerical self-propulsion and tethered models

Hydrodynamic performance analysis of undulating fin propulsion

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