船舶螺旋桨的水动力性能和声学响应

IF 0.8 Q3 ENGINEERING, MARINE

Transactions on Maritime Science-ToMS Pub Date : 2023-04-20 DOI:10.7225/toms.v12.n01.001

S. P. Sanaka, Pardhasaradhi N, D. K

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引用次数: 1

摘要

本文的目的是预测螺旋桨在不同推进比和螺旋桨转速下的水动力性能和噪声。三叶片，DTMB 4119螺旋桨模型创建使用NACA66修改线，a = 0.8水翼剖面。采用ANSYS Workbench软件进行网格生成和计算分析。所有模拟均采用大涡模拟湍流模型和Ffowcs williams - hawkins (FWH)声学模型。采用运动参考系模拟螺旋桨的旋转效应。螺旋桨转速为792转/分，螺旋桨直径为0.2 m，改变进气速度，研究进流比的影响。暂态分析采用时间步长为0.0005秒，总仿真时间为0.6秒。通过与文献实验数据的比较，验证了所得到的水动力性能参数。声压级(SPL)在0到1000hz的频率范围内绘制，在不同的位置、速度和超前比分别为0.5、0.7、0.833和0.9、1。利用双向流固耦合，预测了螺旋桨的结构、声学和水动力性能，提前比为0.833。从分析中得出的主要结论是:声压级值在螺旋桨非设计工况下增加，并且随着接收机位置的变化而变化。本研究所得的数据对设计人员进行进一步的研究，以降低螺旋桨产生的噪声是有用的。

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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Hydrodynamic Performance and Acoustic Response of Ship Propeller

The aim of the paper is to predict the hydrodynamic performance and noise generated by the propeller at different advance ratio and the speed of the propeller. Three bladed, DTMB 4119 propeller model was created using the NACA66 modified line, a = 0.8 hydrofoil profile. ANSYS Workbench software is used for mesh generation and computational analysis. A large-eddy simulation turbulence model and Ffowcs Williams-Hawkings (FWH) acoustic model is used for all simulations. A moving reference frame is used to simulate the rotational effects of the propeller. The speed of the propeller is 792 rpm, the propeller being 0.2 m, and inlet velocity is varied to study the effect of the advance ratio. A transient analysis is carried out using a time step value of 0.0005 seconds and the total simulation time is 0.6 seconds. The hydrodynamic performance parameters are validated by comparing with the experimental data available in the literature. The sound pressure level (SPL) is plotted over the frequency range of 0 to 1000 Hz at different locations, speed, and an advance ratio of 0.5, 0.7, 0.833, and 0.9,1. The structural, acoustic and hydrodynamic behaviour of the propeller was predicted using a two-way fluid structure interaction at an advance ratio of 0.833. The major conclusions drawn from the analysis are that the sound pressure level values are increased at the propeller off-design conditions and varying with the receiver locations. The data generated from this study is useful for the designers to carry out further research in order to reduce the noise generated from the propeller.

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来源期刊

Transactions on Maritime Science-ToMS ENGINEERING, MARINE-

CiteScore

1.50

自引率

12.50%

发文量

期刊介绍： ToMS is a scientific journal with international peer review which publishes papers in the following areas: ~ Marine Engineering, ~ Navigation, ~ Safety Systems, ~ Marine Ecology, ~ Marine Fisheries, ~ Hydrography, ~ Marine Automation and Electronics, ~ Transportation and Modes of Transport, ~ Marine Information Systems, ~ Maritime Law, ~ Management of Marine Systems, ~ Marine Finance, ~ Bleeding-Edge Technologies, ~ Multimodal Transport, ~ Psycho-social and Legal Aspects of Long-term Working Aboard. The journal is published in English as an open access journal, and as a classic paper journal (in limited editions). ToMS aims to present best maritime research from South East Europe, particularly the Mediterranean area. Articles will be double-blind reviewed by three reviewers. With the intention of providing an international perspective at least one of the reviewers will be from abroad. ToMS also promotes scientific collaboration with students and has a section titled Students’ ToMS. These papers also undergo strict peer reviews. Furthermore, the Journal publishes short reviews on significant papers, books and workshops in the fields of maritime science.