On the noise reduction mechanisms of porous aerofoil leading edges
On the noise reduction mechanisms of porous aerofoil leading edges
This paper is predominantly an experimental study into the reduction of turbulence - aerofoil interaction noise by the introduction of aerofoil porosity. In this paper we study three scenarios applied to at plates: (a) when the at plate is fully porous, (b) when the at plate is partially porous from the leading edge and (c) when porosity is introduced downstream of the leading edge. This paper shows that the noise reduction spectra collapse when plotted against non-dimensional frequency fl=U, where l is the length of porous section and U is the flow velocity. Narrow band measurements on a partially porous aerofoil have shown that its noise reduction spectra is characterised by a number of narrow peaks. This paper proposes two main mechanisms for explaining this behaviour. The noise reduction mechanisms are validated against noise reductions measured on a realistic aerofoil at relatively low angles of attack. One of the key findings of this paper is that, by using only a single row of holes downstream of the aerofoil leading edge one can obtain significant levels of noise reduction. This use of downstream porosity is specifically shown to be capable of providing low-frequency noise reductions without increasing the radiated noise at higher frequencies.
Paruchuri, Chaitanya
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Joseph, Phillip
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Chong, Tze Pei
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Priddin, Matthew
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Ayton, Lorna
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27 October 2020
Paruchuri, Chaitanya
5c1def64-6347-4be3-ac2d-b9f6a314b81d
Joseph, Phillip
9c30491e-8464-4c9a-8723-2abc62bdf75d
Chong, Tze Pei
8d9b8213-687b-435d-8baf-b67e9f7055e7
Priddin, Matthew
ad066553-99e6-4373-942a-f6413fffd2fc
Ayton, Lorna
ccf9e6d1-2bf0-4d78-a97c-afd376138856
Paruchuri, Chaitanya, Joseph, Phillip, Chong, Tze Pei, Priddin, Matthew and Ayton, Lorna
(2020)
On the noise reduction mechanisms of porous aerofoil leading edges.
Journal of Sound and Vibration, 485, [115574].
(doi:10.1016/j.jsv.2020.115574).
Abstract
This paper is predominantly an experimental study into the reduction of turbulence - aerofoil interaction noise by the introduction of aerofoil porosity. In this paper we study three scenarios applied to at plates: (a) when the at plate is fully porous, (b) when the at plate is partially porous from the leading edge and (c) when porosity is introduced downstream of the leading edge. This paper shows that the noise reduction spectra collapse when plotted against non-dimensional frequency fl=U, where l is the length of porous section and U is the flow velocity. Narrow band measurements on a partially porous aerofoil have shown that its noise reduction spectra is characterised by a number of narrow peaks. This paper proposes two main mechanisms for explaining this behaviour. The noise reduction mechanisms are validated against noise reductions measured on a realistic aerofoil at relatively low angles of attack. One of the key findings of this paper is that, by using only a single row of holes downstream of the aerofoil leading edge one can obtain significant levels of noise reduction. This use of downstream porosity is specifically shown to be capable of providing low-frequency noise reductions without increasing the radiated noise at higher frequencies.
Text
Porous_JSV_3
- Accepted Manuscript
More information
Accepted/In Press date: 6 July 2020
e-pub ahead of print date: 13 July 2020
Published date: 27 October 2020
Identifiers
Local EPrints ID: 442064
URI: http://eprints.soton.ac.uk/id/eprint/442064
ISSN: 0022-460X
PURE UUID: 3af1d70d-8cc9-445d-86e6-61965e54bde5
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Date deposited: 06 Jul 2020 16:36
Last modified: 17 Mar 2024 05:37
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Author:
Tze Pei Chong
Author:
Matthew Priddin
Author:
Lorna Ayton
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