Downstream porosity for the reduction of turbulence–aerofoil interaction noise
Downstream porosity for the reduction of turbulence–aerofoil interaction noise
This paper is a predominantly experimental study into the use of porosity located downstream of an aerofoil leading edge for the reduction of turbulence interaction noise. Locating the porosity downstream of the leading edge has been shown to be beneficial in reducing the aerodynamic performance penalty compared with locating it directly at the leading edge (Ocker et al., 2021), where most of the lift is generated. Noise measurements on a flat plate with downstream porosity are compared against the case of two flat plates in a tandem configuration. In both cases, the noise reduction spectra exhibit peaks of strong noise reduction at non-dimensional frequencies of fld/Uc=n, where ld is the distance between the leading edge and the downstream edge, Uc is the convection velocity and n is an integer. To explain this behaviour requires a mechanism to be present in which a phase shift of 180∘ is introduced in the interaction process. In the paper we argue that the origin of this phase shift is due to secondary vorticity generated at the leading edge. Another key finding of this paper is that overall noise reductions are due to an effective shortening of the chord in which most of the radiation is produced by the section of the flat plate upstream of the porous section, leading to generally weaker radiation. Neither of these mechanisms have been reported previously in the literature. The paper concludes with noise measurements on a thin aerofoil with downstream porosity included, in which overall noise reductions of up to 2.8 dB are achieved.
Aerofoil noise reduction, Beamforming, Downstream porosity, Turbulence–aerofoil interaction noise
Palleja-Cabre, Sergi
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Chaitanya, Paruchuri
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Joseph, Phillip
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Kim, Jae Wook
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Priddin, Matthew J.
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Ayton, Lorna J.
58d53540-2704-4eaa-acfc-dcaee78637ac
Geyer, Thomas F.
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Chong, Tze Pei
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22 December 2022
Palleja-Cabre, Sergi
b841a96c-05d1-4f08-a197-8693cb3a3f90
Chaitanya, Paruchuri
5c1def64-6347-4be3-ac2d-b9f6a314b81d
Joseph, Phillip
9c30491e-8464-4c9a-8723-2abc62bdf75d
Kim, Jae Wook
fedabfc6-312c-40fd-b0c1-7b4a3ca80987
Priddin, Matthew J.
5d1dd718-f111-4347-8b3e-cd7448896944
Ayton, Lorna J.
58d53540-2704-4eaa-acfc-dcaee78637ac
Geyer, Thomas F.
30e906f9-469a-442f-8c0c-23f44c4977b1
Chong, Tze Pei
5f980a6b-5e53-4491-9920-c663092ad9e7
Palleja-Cabre, Sergi, Chaitanya, Paruchuri, Joseph, Phillip, Kim, Jae Wook, Priddin, Matthew J., Ayton, Lorna J., Geyer, Thomas F. and Chong, Tze Pei
(2022)
Downstream porosity for the reduction of turbulence–aerofoil interaction noise.
Journal of Sound and Vibration, 541, [117324].
(doi:10.1016/j.jsv.2022.117324).
Abstract
This paper is a predominantly experimental study into the use of porosity located downstream of an aerofoil leading edge for the reduction of turbulence interaction noise. Locating the porosity downstream of the leading edge has been shown to be beneficial in reducing the aerodynamic performance penalty compared with locating it directly at the leading edge (Ocker et al., 2021), where most of the lift is generated. Noise measurements on a flat plate with downstream porosity are compared against the case of two flat plates in a tandem configuration. In both cases, the noise reduction spectra exhibit peaks of strong noise reduction at non-dimensional frequencies of fld/Uc=n, where ld is the distance between the leading edge and the downstream edge, Uc is the convection velocity and n is an integer. To explain this behaviour requires a mechanism to be present in which a phase shift of 180∘ is introduced in the interaction process. In the paper we argue that the origin of this phase shift is due to secondary vorticity generated at the leading edge. Another key finding of this paper is that overall noise reductions are due to an effective shortening of the chord in which most of the radiation is produced by the section of the flat plate upstream of the porous section, leading to generally weaker radiation. Neither of these mechanisms have been reported previously in the literature. The paper concludes with noise measurements on a thin aerofoil with downstream porosity included, in which overall noise reductions of up to 2.8 dB are achieved.
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More information
Accepted/In Press date: 23 September 2022
e-pub ahead of print date: 28 September 2022
Published date: 22 December 2022
Additional Information:
Funding Information:
This work is part of the QUADPORS project funded by the EPSRC, United Kingdom ( EP/V00686X/1 ). P. Chaitanya would like to acknowledge the financial support of the Royal Academy of Engineering, United Kingdom ( RF ). M. J. Priddin acknowledges support from EPSRC DTP EP/N509620/1 and support from Christ’s College, University of Cambridge . L. J. Ayton acknowledges support from EPSRC Early Career Fellowship EP/P015980/1 . The authors would also like to thank Oscar Propulsion for the initial funding of this project and Rolls-Royce for continued technical support.
Keywords:
Aerofoil noise reduction, Beamforming, Downstream porosity, Turbulence–aerofoil interaction noise
Identifiers
Local EPrints ID: 471755
URI: http://eprints.soton.ac.uk/id/eprint/471755
ISSN: 0022-460X
PURE UUID: 1eb87bcd-1858-48c4-bafc-a9632f0b6901
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Date deposited: 17 Nov 2022 17:45
Last modified: 18 Mar 2024 03:42
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Contributors
Author:
Matthew J. Priddin
Author:
Lorna J. Ayton
Author:
Thomas F. Geyer
Author:
Tze Pei Chong
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