Bias flow acoustic liner with straight and tapered apertures

Soufiane Ramdani; Nobuhiko Yamasaki; Yuzo Inokuchi; Tatsuya Ishii

doi:10.38036/JGPP.10.3_1

Bias flow acoustic liner with straight and tapered apertures

Soufiane Ramdani, Nobuhiko Yamasaki, Yuzo Inokuchi, Tatsuya Ishii

Thermophysics and Fluid Mechanics

Research output: Contribution to journal › Article › peer-review

Abstract

Experimental and computational studies are performed on slit resonators, i.e., one aperture with a high aspect ratio that spans through the center of the plate. An impedance tube experiment is conducted to investigate the macroscopic response of slit apertures. The test specimens include straight and tapered apertures. Subsequently, the effect of introducing a bias flow is investigated. The absorption performance increases when the sound pressure level increases to a level that causes a production of shed vortices. When a bias flow is introduced, the absorption coefficient reaches its maximum absorption of the incident sound wave in the region near the resonant frequency for a Mach number close to 9.71× ͳͲ^-3. 2D numerical simulations are performed and validated with the experimental results. Good agreement is obtained for the majority of the simulated cases. Vortex shedding and its effect on the absorption coefficients is also investigated.

Original language	English
Pages (from-to)	1-8
Number of pages	8
Journal	International Journal of Gas Turbine, Propulsion and Power Systems
Volume	10
Issue number	3
DOIs	https://doi.org/10.38036/JGPP.10.3_1
Publication status	Published - 2020

All Science Journal Classification (ASJC) codes

Mechanical Engineering

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10.38036/JGPP.10.3_1

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title = "Bias flow acoustic liner with straight and tapered apertures",

abstract = "Experimental and computational studies are performed on slit resonators, i.e., one aperture with a high aspect ratio that spans through the center of the plate. An impedance tube experiment is conducted to investigate the macroscopic response of slit apertures. The test specimens include straight and tapered apertures. Subsequently, the effect of introducing a bias flow is investigated. The absorption performance increases when the sound pressure level increases to a level that causes a production of shed vortices. When a bias flow is introduced, the absorption coefficient reaches its maximum absorption of the incident sound wave in the region near the resonant frequency for a Mach number close to 9.71× ͳͲ-3. 2D numerical simulations are performed and validated with the experimental results. Good agreement is obtained for the majority of the simulated cases. Vortex shedding and its effect on the absorption coefficients is also investigated.",

author = "Soufiane Ramdani and Nobuhiko Yamasaki and Yuzo Inokuchi and Tatsuya Ishii",

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T1 - Bias flow acoustic liner with straight and tapered apertures

AU - Ramdani, Soufiane

AU - Yamasaki, Nobuhiko

AU - Inokuchi, Yuzo

AU - Ishii, Tatsuya

PY - 2020

Y1 - 2020

N2 - Experimental and computational studies are performed on slit resonators, i.e., one aperture with a high aspect ratio that spans through the center of the plate. An impedance tube experiment is conducted to investigate the macroscopic response of slit apertures. The test specimens include straight and tapered apertures. Subsequently, the effect of introducing a bias flow is investigated. The absorption performance increases when the sound pressure level increases to a level that causes a production of shed vortices. When a bias flow is introduced, the absorption coefficient reaches its maximum absorption of the incident sound wave in the region near the resonant frequency for a Mach number close to 9.71× ͳͲ-3. 2D numerical simulations are performed and validated with the experimental results. Good agreement is obtained for the majority of the simulated cases. Vortex shedding and its effect on the absorption coefficients is also investigated.

AB - Experimental and computational studies are performed on slit resonators, i.e., one aperture with a high aspect ratio that spans through the center of the plate. An impedance tube experiment is conducted to investigate the macroscopic response of slit apertures. The test specimens include straight and tapered apertures. Subsequently, the effect of introducing a bias flow is investigated. The absorption performance increases when the sound pressure level increases to a level that causes a production of shed vortices. When a bias flow is introduced, the absorption coefficient reaches its maximum absorption of the incident sound wave in the region near the resonant frequency for a Mach number close to 9.71× ͳͲ-3. 2D numerical simulations are performed and validated with the experimental results. Good agreement is obtained for the majority of the simulated cases. Vortex shedding and its effect on the absorption coefficients is also investigated.

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Bias flow acoustic liner with straight and tapered apertures

Abstract

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