A fundamental study on the performance of tuned mass dampers installed periodically on a fast-rotating train wheel
A fundamental study on the performance of tuned mass dampers installed periodically on a fast-rotating train wheel
Wheel/rail rolling noise is still the main contributor to high-speed train pass-by noise even at 350 km/h. To control wheel vibration and sound radiation, tuned mass dampers (TMDs) may be installed on the wheel. Until now, TMDs have been designed and tested without consideration of wheel rotation, and the effect of wheel rotation on the vibration control performance of the TMDs is unclear. To bridge this gap, a model is developed for predicting the response of a rotating wheel with TMDs subject to a stationary harmonic load, mimicking a harmonic component of the wheel/rail force, so that the effect of wheel rotation on the vibration control performance of the TMDs can be studied. For simplicity, the TMDs are modelled as damped mass-spring systems vibrating either axially or radially without considering the effect of the Coriolis force. The parameters of the TMDs are designed according to the conventional fixed-point theory for dynamic vibration absorbers. The wheel with TMDs is a cyclically periodic structure formed of an axisymmetric structure (the base wheel) and periodically arranged TMDs. In the model, the interaction forces between the base wheel and the TMDs are taken as unknowns. The displacements of the base wheel due to the externally applied load and the interaction forces are formulated based on a previously developed 2.5D FE model of the base wheel. It is shown that the interaction forces can be decomposed into frequency components to be determined by solving a set of linear algebraic equations. Results are produced for a typical high-speed train wheel with different numbers of TMDs of different tuning frequencies. The results show that, the fixed-point theory for dynamic vibration absorber may be used to design TMDs for a fast-rotating train wheel, although the design may not be optimal; for a given total mass of TMDs and a given mode of the base wheel, the number of TMDs should be 2 times the nodal number of the mode plus 1.
Peng, Yuhao
5d5a30b1-8816-4f83-ab7b-a76462ecdb7c
Zhang, Dechun
1c86cadf-ce43-4d73-b5d5-88beef21a9d9
Sheng, Xiaozhen
4b778204-a77a-4999-9919-38cd03e540db
Thompson, David
bca37fd3-d692-4779-b663-5916b01edae5
29 January 2024
Peng, Yuhao
5d5a30b1-8816-4f83-ab7b-a76462ecdb7c
Zhang, Dechun
1c86cadf-ce43-4d73-b5d5-88beef21a9d9
Sheng, Xiaozhen
4b778204-a77a-4999-9919-38cd03e540db
Thompson, David
bca37fd3-d692-4779-b663-5916b01edae5
Peng, Yuhao, Zhang, Dechun, Sheng, Xiaozhen and Thompson, David
(2024)
A fundamental study on the performance of tuned mass dampers installed periodically on a fast-rotating train wheel.
Journal of Sound and Vibration, 576.
Abstract
Wheel/rail rolling noise is still the main contributor to high-speed train pass-by noise even at 350 km/h. To control wheel vibration and sound radiation, tuned mass dampers (TMDs) may be installed on the wheel. Until now, TMDs have been designed and tested without consideration of wheel rotation, and the effect of wheel rotation on the vibration control performance of the TMDs is unclear. To bridge this gap, a model is developed for predicting the response of a rotating wheel with TMDs subject to a stationary harmonic load, mimicking a harmonic component of the wheel/rail force, so that the effect of wheel rotation on the vibration control performance of the TMDs can be studied. For simplicity, the TMDs are modelled as damped mass-spring systems vibrating either axially or radially without considering the effect of the Coriolis force. The parameters of the TMDs are designed according to the conventional fixed-point theory for dynamic vibration absorbers. The wheel with TMDs is a cyclically periodic structure formed of an axisymmetric structure (the base wheel) and periodically arranged TMDs. In the model, the interaction forces between the base wheel and the TMDs are taken as unknowns. The displacements of the base wheel due to the externally applied load and the interaction forces are formulated based on a previously developed 2.5D FE model of the base wheel. It is shown that the interaction forces can be decomposed into frequency components to be determined by solving a set of linear algebraic equations. Results are produced for a typical high-speed train wheel with different numbers of TMDs of different tuning frequencies. The results show that, the fixed-point theory for dynamic vibration absorber may be used to design TMDs for a fast-rotating train wheel, although the design may not be optimal; for a given total mass of TMDs and a given mode of the base wheel, the number of TMDs should be 2 times the nodal number of the mode plus 1.
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Accepted/In Press date: 15 January 2024
e-pub ahead of print date: 16 January 2024
Published date: 29 January 2024
Identifiers
Local EPrints ID: 487535
URI: http://eprints.soton.ac.uk/id/eprint/487535
ISSN: 0022-460X
PURE UUID: 1b0bdd6e-ce23-493a-ae94-387a64a02b68
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Date deposited: 22 Feb 2024 18:44
Last modified: 18 Mar 2024 02:43
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Contributors
Author:
Yuhao Peng
Author:
Dechun Zhang
Author:
Xiaozhen Sheng
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