Experimental study and numerical simulation of hydrodynamics for fish-like underwater vehicle

Robotics and Technical Cybernetics Pub Date : 2023-03-01 DOI:10.31776/rtcj.11105

N. Tschur, Iliya Mitin, R. Korotaev, V. Mironov, V. Kazantsev

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Abstract

This article presents the results of experimental and computational modeling of the movement of a fish-like underwater robot. The experimental 3D model is constructed from photographs of Pacific bluefin tuna. This model allows us to study biomorphic swimming with various motion parameters, namely: the amplitude and frequency of strokes is set by the servo control signal, the angle between the tail fin and the elastic plate is set by the number and stiffness of springs in the hinge. The calculation method involves the joint solution of the equations of dynamics of the robot and the equations of hydrodynamics of the fluid flowing around it. For this task, an original mesh deformation algorithm was developed that allows hydrodynamic calculations to be performed near the tail of the model performing transverse oscillations. The use of deformable mesh technology allows you to reproduce the shape of the tail vibrations as accurately as possible. In addition, the calculation scheme has the property of conservativeness, which makes it possible to obtain high quality calculations, confirmed by comparison with experimental data.

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鱼状水下航行器流体力学实验研究与数值模拟

本文介绍了一种鱼状水下机器人运动的实验结果和计算模型。实验三维模型是根据太平洋蓝鳍金枪鱼的照片构建的。该模型允许我们研究具有各种运动参数的仿生游泳，即:划动的幅度和频率由伺服控制信号设定，尾鳍与弹性板之间的角度由铰链中弹簧的数量和刚度设定。计算方法包括机器人的动力学方程和其周围流体的流体动力学方程的联合求解。为此，开发了一种原始网格变形算法，该算法允许在执行横向振荡的模型尾部附近进行水动力计算。使用可变形网格技术，您可以尽可能准确地再现尾部振动的形状。此外，该计算方案具有保守性，可以获得高质量的计算结果，并与实验数据进行了比较。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Robotics and Technical Cybernetics

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