An experimental study of aerodynamic noise from large obstructions in turbulent boundary layer flows

This paper reports an experimental study on the aerodynamic noise generated by a two-dimensional large obstacle in a turbulent boundary layer. Square and triangular obstacles with varying heights of h / δ = 0.48 , 0.8 , 1.2 , 1.6, and 2 (where δ is the boundary layer thickness measured without the o...

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Bibliographic Details
Published in:Physics of fluids (1994) 2022-02, Vol.34 (2)
Main Authors: Sundeep, Shivam, Bu, Huanxian, Zhou, Peng, Zhong, Siyang, Zhang, Xin
Format: Article
Language:English
Subjects:
Aerodynamic noise
Barriers
Boundary layer flow
Boundary layer thickness
Broadband
Dipoles
Directivity
Fluid dynamics
Fluid flow
Hydrodynamic pressure
LF noise
Noise control
Obstructions
Physics
Reynolds number
Sound diffraction
Sound waves
Thickness measurement
Turbulence
Turbulent boundary layer
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Summary:This paper reports an experimental study on the aerodynamic noise generated by a two-dimensional large obstacle in a turbulent boundary layer. Square and triangular obstacles with varying heights of h / δ = 0.48 , 0.8 , 1.2 , 1.6, and 2 (where δ is the boundary layer thickness measured without the obstacle present) are tested at various flow speeds ranging from 20 to 50 m/s. The Reynolds number based on step height and free stream velocity ranged between 7500 and 79 000. A linear microphone array is arranged aside to measure the sound radiation in the spanwise direction. It is suggested that both square and triangular obstructions can lead to a broadband source with a dipole-type directivity. A consistent increase in the noise strength is observed with obstacle height and flow speed. The underlying noise source is revealed by comparing the acoustic spectra of different obstacle geometries. The low-frequency noise is contributed by the turbulence modification due to the flow impingement onto the obstacle, while the high-frequency sound is mainly caused by the diffraction of hydrodynamic pressure by the sharp leading edge.
ISSN:1070-6631
1089-7666
DOI:10.1063/5.0080426