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两种适用于海豚的游泳模式的流体动力学比较与协作研究

A Comparative and Collaborative Study of the Hydrodynamics of Two Swimming Modes Applicable to Dolphins.

作者信息

Xia Dan, Li Zhihan, Lei Ming, Yan Han, Zhou Zilong

机构信息

School of Mechanical Engineering, Southeast University, Nanjing 211189, China.

出版信息

Biomimetics (Basel). 2023 Jul 14;8(3):311. doi: 10.3390/biomimetics8030311.

DOI:10.3390/biomimetics8030311
PMID:37504199
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10807648/
Abstract

This paper presents a hydrodynamics study that examines the comparison and collaboration of two swimming modes relevant to the universality of dolphins. This study utilizes a three-dimensional virtual swimmer model resembling a dolphin, which comprises a body and/or caudal fin (BCF) module, as well as a medium and/or paired fin (MPF) module, each equipped with predetermined kinematics. The manipulation of the dolphin to simulate various swimming modes is achieved through the application of overlapping grids in conjunction with the parallel hole cutting technique. The findings demonstrate that the swimming velocity and thrust attained through the single BCF mode consistently surpass those achieved through the single MPF mode and collaborative mode. Interestingly, the involvement of the MPF mode does not necessarily contribute to performance enhancement. Nevertheless, it is encouraging to note that adjusting the phase difference between the two modes can partially mitigate the limitations associated with the MPF mode. To further investigate the potential advantages of dual-mode collaboration, we conducted experiments by increasing the MPF frequency while keeping the BCF frequency constant, thus introducing the concept of frequency ratio (). In comparison to the single BCF mode, the collaborative mode with a high exhibits superior swimming velocity and thrust. Although its efficiency experiences a slight decrease, it tends to stabilize. The corresponding flow structure indirectly verifies the favorable impact of collaboration.

摘要

本文介绍了一项流体动力学研究,该研究考察了与海豚普遍性相关的两种游泳模式的比较与协作。本研究利用了一个类似于海豚的三维虚拟游泳者模型,该模型包括一个身体和/或尾鳍(BCF)模块以及一个中间和/或成对鳍(MPF)模块,每个模块都配备了预定的运动学。通过应用重叠网格结合平行孔切割技术来操纵海豚以模拟各种游泳模式。研究结果表明,通过单一BCF模式获得的游泳速度和推力始终超过通过单一MPF模式和协作模式获得的速度和推力。有趣的是,MPF模式的参与并不一定有助于提高性能。然而,值得欣慰的是,调整两种模式之间的相位差可以部分减轻与MPF模式相关的局限性。为了进一步研究双模式协作的潜在优势,我们通过在保持BCF频率不变的情况下增加MPF频率进行了实验,从而引入了频率比()的概念。与单一BCF模式相比,具有高频率比的协作模式表现出更高的游泳速度和推力。虽然其效率略有下降,但趋于稳定。相应的流动结构间接验证了协作的有利影响。

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