Study on influencing factors of hydrodynamics based on AUV docking with conical dock

IF 1.5 4区 工程技术 Q3 ENGINEERING, MARINE
Jiayu Diao, Weimin Li, Xueqing Yuan, Kai Jiang, Yifeng Zhao
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引用次数: 1

Abstract

It is necessary to investigate the dynamic performance during autonomous underwater vehicle (AUV) underwater docking to aid in control and to enhance docking safety. Therefore, in this study, the docking hydrodynamic characteristics (including the docking system’s streamline, velocity vector, and surface pressure during the overall docking process) of the AUV with conical hood dock are determined by using the dynamic grid technology, and the water drag force situations of the AUV docking with conical hood dock are studied from the perspectives of different velocities, accelerations, navigation modes, and structures. Additionally, the multiple nonlinear regression fits and the preliminary docking test were examined. Furthermore, brief inferences obtained are as follows: First, the maximum pressure is situated at the upstream surface of the dock conical hood and the head of the AUV, and the maximum rotation angle of the streamline is situated at the outermost ring of dock conical hood. Within a specified range, the rotation angle of the streamline affected by the conical hood progressively declines as the AUV docks deeper into the conical hood. Second, low velocity uniform docking, deceleration docking, and chase docking can reduce the drag force to a certain extent during docking. Finally, both arc shape and mesh structure can decrease the water drag force of docking to a specified degree. This research provides a theoretical basis and reference methods for the dynamic research of the docking system, and other related research can be carried out through the methods and results of this research.
基于锥形船坞的水下航行器对接水动力影响因素研究
研究自主水下航行器(AUV)在水下对接过程中的动力学特性,有助于控制和提高对接安全性。因此,本研究采用动态网格技术确定了锥形罩坞AUV的对接水动力特性(包括对接系统流线、速度矢量、整体对接过程中的表面压力),并从不同速度、加速度、导航方式、结构等角度研究了锥形罩坞AUV对接时的水阻力情况。并进行了多元非线性回归拟合和初步对接试验。由此得出如下结论:第一,最大压力位于船坞锥罩上游表面和水下航行器头部,流线最大转角位于船坞锥罩最外环处。在一定范围内,受锥形罩影响的流线的旋转角度随着AUV进入锥形罩的深度而逐渐减小。其次,低速均匀对接、减速对接和追逐对接可以在一定程度上减小对接过程中的阻力。最后,圆弧形状和网格结构都能在一定程度上减小对接的水阻力。本研究为对接系统的动力学研究提供了理论基础和参考方法,其他相关研究可以通过本研究的方法和成果进行。
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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来源期刊
CiteScore
3.90
自引率
11.10%
发文量
77
审稿时长
>12 weeks
期刊介绍: The Journal of Engineering for the Maritime Environment is concerned with the design, production and operation of engineering artefacts for the maritime environment. The journal straddles the traditional boundaries of naval architecture, marine engineering, offshore/ocean engineering, coastal engineering and port engineering.
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