Time domain broadband noise predictions for non-cavitating marine propellers with wall pressure spectrum models

Time domain broadband noise predictions for non-cavitating marine propellers with wall pressure spectrum models

The broadband noise can be dominant or important for total characteristics for marine propeller noise representing the minimum base of self-noise. Accurate prediction of such noise is crucial for survivability of underwater military vessels. While the FW-H Formulation 1B can be used to predict broad...

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Bibliographic Details
Published in:International journal of naval architecture and ocean engineering Vol. 13; pp. 75 - 85
Main Authors: Choi, Woen-Sug, Hong, Suk-Yoon, Song, Jee-Hun, Kwon, Hyun-Wung, Park, Il-Ryong, Seol, Han-Shin, Kim, Min-Jae
Format: Journal Article
Language:English
Published: Elsevier B.V 01-11-2021
Elsevier
대한조선학회
Subjects:
Flow noise
Marine propeller
Non-cavitation noise
Submarine
Wall pressure spectrum
조선공학
Flow noise
Non-cavitation noise
Submarine
Marine propeller
Wall pressure spectrum
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Summary:The broadband noise can be dominant or important for total characteristics for marine propeller noise representing the minimum base of self-noise. Accurate prediction of such noise is crucial for survivability of underwater military vessels. While the FW-H Formulation 1B can be used to predict broadband trailing edge noise, the method required experiment measurements of surface pressure correlations, showing its limitations in generality. Therefore, in this study, the methods are developed to utilize wall pressure spectrum models to overcome those limitations. Chase model is adopted to represent surface pressure along with the developed formulations to reproduce pressure statistics. Newly developed method is validated with the experiments of airfoils at different velocities. Thereafter, with its feasibility and generality, the procedure incorporating computational fluid dynamics is established and performed for a propeller behind submarine hull. The results are compared with the experiments conducted at Large Cavitation Tunnel, thus showing its usability and robustness.
ISSN:2092-6782
2092-6790
DOI:10.1016/j.ijnaoe.2021.01.004