螺旋桨空化噪声的计算预测

The 9th Conference on Computational Methods in Marine Engineering (Marine 2021) Pub Date : 2022-01-31 DOI:10.2218/marine2021.6784

M. Kalikatzarakis, Andrea Coraddu, M. Atlar, G. Tani, S. Gaggero, D. Villa, L. Oneto

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引用次数: 0

摘要

船舶水下辐射噪声对海洋动物的潜在影响已成为一个重要问题。螺旋桨驱动船舶最主要的噪声源是螺旋桨空化，其噪声特征的准确预测是设计过程的基础。在这项工作中，我们研究了使用低计算成本方法来预测空化船用螺旋桨的URN的潜力，这种方法可以在设计过程中方便地实现。我们比较了子午线标准螺旋桨系列的一个子集，在不同程度的轴向尾迹下的计算和实验结果，总共进行了432次实验。

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Computational Prediction of Propeller Cavitation Noise

The potential impact of ships underwater radiated noise (URN) on marine fauna has become an important issue. The most dominant noise source on a propeller-driven vessel is propeller cavitation, and the accurate prediction of its noise signature is fundamental for the design process. In this work, we investigate the potential of using low-computational-cost methods for the prediction of URN from cavitating marine propellers that can be conveniently implemented within the design process. We compare computational and experimental results on a subset of the Meridian standard propeller series, behind different severities of axial wake, for a total of 432 experiments.

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The 9th Conference on Computational Methods in Marine Engineering (Marine 2021)

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