An analytical and experimental investigation of aerofoil-turbulence interaction noise for plates with spanwise-varying leading edges
An analytical and experimental investigation of aerofoil-turbulence interaction noise for plates with spanwise-varying leading edges
This paper presents an analytic solution for gust-aerofoil interaction noise for flat plates with spanwise-varying periodic leading edges in uniform mean flow. The solution is obtained by solving the linear inviscid equations via separation of variables and the Wiener-Hopf technique, and is suitable for calculating the far-field noise generated by any leading-edge with a single-valued piecewise linear periodic spanwise geometry. Acoustic results for homogeneous isotropic turbulent flow are calculated by integrating the single-gust solution over a wavenumber spectrum. The far-sound pressure level is calculated for five test case geometries; sawtooth serration, slitted v-root, slitted u-root, chopped peak, and square wave, and compared to experimental measurements. Good agreement is seen over a range of frequencies and tip-to-root ratios (varying the sharpness of the serration). The analytic solution is then used to calculate the propagating pressure along the leading-edge of the serration for fixed spanwise wavenumbers, i.e. only the contribution to the surface pressure which propagates to the far field. Using these results, two primary mechanisms for noise reduction are discussed; tip and root interference, and a redistribution of energy from cuton modes to cut off modes. A secondary noise-reduction mechanism due to non-linear features is also discussed and seen to be particularly important for leading edges with very narrow slits.
137-168
Ayton, Lorna J.
58d53540-2704-4eaa-acfc-dcaee78637ac
Paruchuri, Chaitanya
5c1def64-6347-4be3-ac2d-b9f6a314b81d
25 April 2019
Ayton, Lorna J.
58d53540-2704-4eaa-acfc-dcaee78637ac
Paruchuri, Chaitanya
5c1def64-6347-4be3-ac2d-b9f6a314b81d
Ayton, Lorna J. and Paruchuri, Chaitanya
(2019)
An analytical and experimental investigation of aerofoil-turbulence interaction noise for plates with spanwise-varying leading edges.
Journal of Fluid Mechanics, 865, .
(doi:10.1017/jfm.2019.78).
Abstract
This paper presents an analytic solution for gust-aerofoil interaction noise for flat plates with spanwise-varying periodic leading edges in uniform mean flow. The solution is obtained by solving the linear inviscid equations via separation of variables and the Wiener-Hopf technique, and is suitable for calculating the far-field noise generated by any leading-edge with a single-valued piecewise linear periodic spanwise geometry. Acoustic results for homogeneous isotropic turbulent flow are calculated by integrating the single-gust solution over a wavenumber spectrum. The far-sound pressure level is calculated for five test case geometries; sawtooth serration, slitted v-root, slitted u-root, chopped peak, and square wave, and compared to experimental measurements. Good agreement is seen over a range of frequencies and tip-to-root ratios (varying the sharpness of the serration). The analytic solution is then used to calculate the propagating pressure along the leading-edge of the serration for fixed spanwise wavenumbers, i.e. only the contribution to the surface pressure which propagates to the far field. Using these results, two primary mechanisms for noise reduction are discussed; tip and root interference, and a redistribution of energy from cuton modes to cut off modes. A secondary noise-reduction mechanism due to non-linear features is also discussed and seen to be particularly important for leading edges with very narrow slits.
Text
ArbitraryLE_Submitted
- Accepted Manuscript
More information
Accepted/In Press date: 18 January 2019
e-pub ahead of print date: 18 February 2019
Published date: 25 April 2019
Identifiers
Local EPrints ID: 428580
URI: http://eprints.soton.ac.uk/id/eprint/428580
ISSN: 0022-1120
PURE UUID: 06439d1c-0258-4c50-a181-24ed20691145
Catalogue record
Date deposited: 01 Mar 2019 17:30
Last modified: 16 Mar 2024 07:36
Export record
Altmetrics
Contributors
Author:
Lorna J. Ayton
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics