门舵®系统相对于传统尾舵的水动力和声学性能实验研究

IF 4.6 2区 工程技术 Q1 ENGINEERING, CIVIL Ocean Engineering Pub Date : 2024-11-16 DOI:10.1016/j.oceaneng.2024.119742
Ivan Santic, Salvatore Mauro, Mario Felli
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引用次数: 0

摘要

门舵(Gate Rudder®)是一种新概念的节能装置和操纵系统,由螺旋桨两侧的两个不对称独立桨叶组成,具有提供额外推力(类似于加速管道推进器)的优势,并可通过对每个舵叶的单独控制来增强船舶的操纵性和稳航能力。本研究报告汇报了一项综合实验调查的结果,其中针对一艘集装箱船,调查了门舵®系统(GRS)与传统尾舵(CRS)的水动力和水声性能。这项调查是在欧盟 H2020 研究项目 "GATERS "的框架内进行的,包括通过 2D-PIV 和立体 PIV 进行的详细流动测量、气蚀测试以及对目标集装箱船缩放模型进行的声学测量。测试矩阵包括不同的舵/舵叶角度、速度和位移。该研究强调了安装闸舵(Gate Rudder®)相对于传统尾舵在消声方面的有益效果,并揭示了不同工作条件下螺旋桨尾流与闸舵叶片相互作用的基本流体力学机制。
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Experimental Investigation of the hydrodynamic and acoustic performance of a Gate Rudder® system over a conventional rudder
The Gate Rudder® is a new concept of energy saving device and manoeuvring system, consisting of two asymmetric and independent blades at each side of a propeller which combines the advantage to deliver additional thrust, similar to an accelerating ducted propulsor, and to enhance ship manoeuvrability and seakeeping ability due to the individual control of each rudder blades.
The present study reports the results of a comprehensive experimental survey in which the hydrodynamic and hydro-acoustic performances of a Gate Rudder® system (GRS) were investigated with respect to a conventional rudder (CRS), for a reference container vessel. The survey, that was conducted in the framework of the EU H2020 Research Project “GATERS”, included detailed flow measurements by 2D-PIV and Stereo-PIV, cavitation tests and acoustic measurements on a scaled model of a target container ship. The tests matrix covered different rudder/rudder-blade angles, speeds and displacements. The study highlights the beneficial effects provided by the installation of a Gate Rudder® over a conventional rudder in terms of sound mitigation and reveals the fundamental underlying hydrodynamic mechanisms of the propeller wake interaction with the Gate Rudder blades under different operative conditions.
The results provide useful insights on how to improve the hydrodynamic and acoustic performance of a GRS.
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来源期刊
Ocean Engineering
Ocean Engineering 工程技术-工程:大洋
CiteScore
7.30
自引率
34.00%
发文量
2379
审稿时长
8.1 months
期刊介绍: Ocean Engineering provides a medium for the publication of original research and development work in the field of ocean engineering. Ocean Engineering seeks papers in the following topics.
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