Analytical investigation of propeller-wing interaction noise
Analytical investigation of propeller-wing interaction noise
This paper investigates the noise generated by propeller-wing configuration at take-off condition with the propeller mounted upstream. This study makes use of various axisymmetric noise models developed for contra-rotating propellers to estimate the noise generated by propeller-wing configuration and later integrate them to estimate total noise. First, using well-published theory, rotor-alone (loading, thickness, and self-noise) and interaction noise sources (viscous-wake, potential field, tip-vortex) including tonal and broadband components are estimated. Later, a systematic parametric study is carried out by changing the blade number and tip Mach, while maintaining the propeller thrust and blade solidity. The noise generated is represented by Overall Acoustic Sound Power Level (OSWLs), which is an integrated value over the emission angles and frequency range, in a matrix form for the range of blade number and tip Mach. This matrix shows the regions dominated by rotor-alone and interaction noise and found that the noise characteristics of a rotor in uninstalled conditions (rotor-alone) are significantly altered due to the presence of a wing (installed condition). Further, it is found that the balance between these regions shifts with the variation in separation distance between the propeller and the wing. These results are further discussed with the individual interaction noise source mechanism and their dominance at various blade numbers, tip Mach, and separation distances. In addition, the non-axisymmetric viscous-wake interaction noise is investigated for even and odd numbers of blades and found that viscous-wake interaction noise has considerable directivity in the azimuthal direction. The results presented in the study are preliminary findings of propeller-wing noise, however, it gives give a quantitative picture of the behaviour of various noise sources and their balance with respect to geometric and operating parameters. This study will help to understand the dominant noise sources involved in propeller-wing configuration and will provide a quick guide for designing a low-noise configuration.
Aerospace Research Central
Akiwate, Deepak C.
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Parry, Anthony
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Joseph, Phillip
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Paruchuri, Chaitanya C.
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Akiwate, Deepak C.
b6f50d26-e59b-413e-9c66-0ee0a869813c
Parry, Anthony
77463a31-d1dd-4f20-9ec3-9cce4f5972b2
Joseph, Phillip
3e896a88-9ea6-42e9-98b7-783e4fe27ff0
Paruchuri, Chaitanya C.
bfff499b-3268-4fb2-bb22-b064195baef9
Akiwate, Deepak C., Parry, Anthony, Joseph, Phillip and Paruchuri, Chaitanya C.
(2022)
Analytical investigation of propeller-wing interaction noise.
In 28th AIAA/CEAS Aeroacoustics 2022 Conference.
Aerospace Research Central..
(doi:10.2514/6.2022-2877).
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Conference or Workshop Item
(Paper)
Abstract
This paper investigates the noise generated by propeller-wing configuration at take-off condition with the propeller mounted upstream. This study makes use of various axisymmetric noise models developed for contra-rotating propellers to estimate the noise generated by propeller-wing configuration and later integrate them to estimate total noise. First, using well-published theory, rotor-alone (loading, thickness, and self-noise) and interaction noise sources (viscous-wake, potential field, tip-vortex) including tonal and broadband components are estimated. Later, a systematic parametric study is carried out by changing the blade number and tip Mach, while maintaining the propeller thrust and blade solidity. The noise generated is represented by Overall Acoustic Sound Power Level (OSWLs), which is an integrated value over the emission angles and frequency range, in a matrix form for the range of blade number and tip Mach. This matrix shows the regions dominated by rotor-alone and interaction noise and found that the noise characteristics of a rotor in uninstalled conditions (rotor-alone) are significantly altered due to the presence of a wing (installed condition). Further, it is found that the balance between these regions shifts with the variation in separation distance between the propeller and the wing. These results are further discussed with the individual interaction noise source mechanism and their dominance at various blade numbers, tip Mach, and separation distances. In addition, the non-axisymmetric viscous-wake interaction noise is investigated for even and odd numbers of blades and found that viscous-wake interaction noise has considerable directivity in the azimuthal direction. The results presented in the study are preliminary findings of propeller-wing noise, however, it gives give a quantitative picture of the behaviour of various noise sources and their balance with respect to geometric and operating parameters. This study will help to understand the dominant noise sources involved in propeller-wing configuration and will provide a quick guide for designing a low-noise configuration.
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e-pub ahead of print date: 13 June 2022
Additional Information:
Funding Information: the authors would like to acknowledge Rolls-Royce PLC for the financial and technical support through the Institute of Sound and Vibration Research, University of Southampton.
Venue - Dates:
28th AIAA/CEAS Aeroacoustics 2022 Conference, Hilton at the Ageas Bowl, Southampton, United Kingdom, 2022-06-14 - 2022-06-17
Identifiers
Local EPrints ID: 472516
URI: http://eprints.soton.ac.uk/id/eprint/472516
PURE UUID: b390ac76-e10f-4789-acf1-ce0d9e52122f
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Date deposited: 07 Dec 2022 17:46
Last modified: 16 Mar 2024 23:12
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Contributors
Author:
Deepak C. Akiwate
Author:
Anthony Parry
Author:
Phillip Joseph
Author:
Chaitanya C. Paruchuri
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