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The noise generated by a landing gear wheel with hub and rim cavities

The noise generated by a landing gear wheel with hub and rim cavities
The noise generated by a landing gear wheel with hub and rim cavities
Wheels are one of the major noise sources of landing gears. Accurate numerical predictions of wheel noise can provide an insight into the physical mechanism of landing gear noise generation and can aid in the design of noise control devices. The major noise sources of a 33% scaled isolated landing gear wheel are investigated by simulating three different wheel configurations using high-order numerical simulations to compute the flow field and the FW-H equation to obtain the far-field acoustic pressures. The baseline configuration is a wheel with a hub cavity and two rim cavities. Two additional simulations are performed; one with the hub cavity covered (NHC) and the other with both the hub cavity and rim cavities covered (NHCRC). These simulations isolate the effects of the hub cavity and rim cavities on the overall wheel noise. The surface flow patterns are visualised by shear stress lines and show that the flow separations and attachments on the side of the wheel, in both the baseline and the configuration with only the hub cavity covered, are significantly reduced by covering both the hub and rim cavities. A frequency-domain FW-H equation is used to identify the noise source regions on the surface of the wheel. The tyre is the main low frequency noise source and shows a lift dipole and side force dipole pattern depending on the frequency. The hub cavity is identified as the dominant middle frequency noise source and radiates in a frequency range centered around the first and second depth modes of the cylindrical hub cavity. The rim cavities are the main high-frequency noise sources. With the hub cavity and rim cavities covered, the largest reduction in Overall Sound Pressure Level (OASPL) is achieved in the hub side direction. In the other directivities, there is also a reduction in the radiated sound.
0022-460X
127-141
Wang, M.
66a75e8c-a780-4fe8-8aa6-b37e80a6c134
Angland, D.
b86880c6-31fa-452b-ada8-4bbd83cda47f
Zhang, X.
2a998468-40dc-4bff-b640-5c7bf74b416b
Wang, M.
66a75e8c-a780-4fe8-8aa6-b37e80a6c134
Angland, D.
b86880c6-31fa-452b-ada8-4bbd83cda47f
Zhang, X.
2a998468-40dc-4bff-b640-5c7bf74b416b

Wang, M., Angland, D. and Zhang, X. (2017) The noise generated by a landing gear wheel with hub and rim cavities. Journal of Sound and Vibration, 392, 127-141. (doi:10.1016/j.jsv.2016.12.045).

Record type: Article

Abstract

Wheels are one of the major noise sources of landing gears. Accurate numerical predictions of wheel noise can provide an insight into the physical mechanism of landing gear noise generation and can aid in the design of noise control devices. The major noise sources of a 33% scaled isolated landing gear wheel are investigated by simulating three different wheel configurations using high-order numerical simulations to compute the flow field and the FW-H equation to obtain the far-field acoustic pressures. The baseline configuration is a wheel with a hub cavity and two rim cavities. Two additional simulations are performed; one with the hub cavity covered (NHC) and the other with both the hub cavity and rim cavities covered (NHCRC). These simulations isolate the effects of the hub cavity and rim cavities on the overall wheel noise. The surface flow patterns are visualised by shear stress lines and show that the flow separations and attachments on the side of the wheel, in both the baseline and the configuration with only the hub cavity covered, are significantly reduced by covering both the hub and rim cavities. A frequency-domain FW-H equation is used to identify the noise source regions on the surface of the wheel. The tyre is the main low frequency noise source and shows a lift dipole and side force dipole pattern depending on the frequency. The hub cavity is identified as the dominant middle frequency noise source and radiates in a frequency range centered around the first and second depth modes of the cylindrical hub cavity. The rim cavities are the main high-frequency noise sources. With the hub cavity and rim cavities covered, the largest reduction in Overall Sound Pressure Level (OASPL) is achieved in the hub side direction. In the other directivities, there is also a reduction in the radiated sound.

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More information

Accepted/In Press date: 29 December 2016
e-pub ahead of print date: 7 January 2017
Organisations: Aerodynamics & Flight Mechanics Group

Identifiers

Local EPrints ID: 404269
URI: http://eprints.soton.ac.uk/id/eprint/404269
DOI: doi:10.1016/j.jsv.2016.12.045
ISSN: 0022-460X
PURE UUID: 5a774e06-c04f-4068-8e27-6b102d76cfbe

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Date deposited: 05 Jan 2017 11:26
Last modified: 15 Mar 2024 06:11

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Contributors

Author: M. Wang
Author: D. Angland
Author: X. Zhang

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