Transition radiation in an infinite one-dimensional structure interacting with a moving oscillator—the Green’s function method

Transition zones in railway tracks are areas with considerable variation of track properties (e.g., foundation stiffness) which may cause strong amplification of the response, leading to rapid degradation of the track geometry. Two possible indicators of degradation in the supporting structure are i...

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Veröffentlicht in:	Journal of sound and vibration 2021-02, Vol.492, p.115804, Article 115804
Hauptverfasser:	Fărăgău, Andrei B., Mazilu, Traian, Metrikine, Andrei V., Lu, Tao, van Dalen, Karel N.
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Sprache:	eng
Schlagworte:	Boundary conditions Contact force Degradation Euler-Bernoulli beams Eulers equations Finite difference method Green's functions Green’s function method Indicators Infinite system Inhomogeneous system Mathematical models Moving oscillator Non-reflective boundaries One dimensional models Railway networks Railway tracks Rolling contact Sound amplification Stiffness Tracking control systems Transition radiation Vibration
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container_title	Journal of sound and vibration
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description	Transition zones in railway tracks are areas with considerable variation of track properties (e.g., foundation stiffness) which may cause strong amplification of the response, leading to rapid degradation of the track geometry. Two possible indicators of degradation in the supporting structure are identified, namely the wheel-rail contact force and the power/energy input by the vehicle. This paper analyses the influence of accounting for the interaction between the vehicle and the supporting structure on the contact force and on the power/energy input. To this end, a one-dimensional model is formulated, consisting of an infinite Euler-Bernoulli beam resting on a locally inhomogeneous Kelvin foundation, interacting with a moving loaded oscillator that has a nonlinear Hertzian spring. The solution is obtained using the Green’s-function method. To obtain the Green’s function of the inhomogeneous and infinite beam-foundation sub-system, the finite difference method is used for the spatial discretization and non-reflective boundary conditions are applied. Accounting for the interaction between the moving oscillator and the supporting structure generally leads to stronger wave radiation, caused by the variation of the vertical momentum of the moving mass. Results show that for relatively high velocity and small transition length, the maximum contact force as well as the energy input exhibit a significant increase compared to the moving constant load case. Furthermore, for relatively high velocities, the maximum contact force also increases significantly with increasing stiffness dissimilarity, findings which supplement the existing literature. Finally, the two degradation indicators can be used in the preliminary stages of design to assess the performance of railway track transition zones.
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Two possible indicators of degradation in the supporting structure are identified, namely the wheel-rail contact force and the power/energy input by the vehicle. This paper analyses the influence of accounting for the interaction between the vehicle and the supporting structure on the contact force and on the power/energy input. To this end, a one-dimensional model is formulated, consisting of an infinite Euler-Bernoulli beam resting on a locally inhomogeneous Kelvin foundation, interacting with a moving loaded oscillator that has a nonlinear Hertzian spring. The solution is obtained using the Green’s-function method. To obtain the Green’s function of the inhomogeneous and infinite beam-foundation sub-system, the finite difference method is used for the spatial discretization and non-reflective boundary conditions are applied. Accounting for the interaction between the moving oscillator and the supporting structure generally leads to stronger wave radiation, caused by the variation of the vertical momentum of the moving mass. Results show that for relatively high velocity and small transition length, the maximum contact force as well as the energy input exhibit a significant increase compared to the moving constant load case. Furthermore, for relatively high velocities, the maximum contact force also increases significantly with increasing stiffness dissimilarity, findings which supplement the existing literature. Finally, the two degradation indicators can be used in the preliminary stages of design to assess the performance of railway track transition zones.</description><identifier>ISSN: 0022-460X</identifier><identifier>EISSN: 1095-8568</identifier><identifier>DOI: 10.1016/j.jsv.2020.115804</identifier><language>eng</language><publisher>Amsterdam: Elsevier Ltd</publisher><subject>Boundary conditions ; Contact force ; Degradation ; Euler-Bernoulli beams ; Eulers equations ; Finite difference method ; Green's functions ; Green’s function method ; Indicators ; Infinite system ; Inhomogeneous system ; Mathematical models ; Moving oscillator ; Non-reflective boundaries ; One dimensional models ; Railway networks ; Railway tracks ; Rolling contact ; Sound amplification ; Stiffness ; Tracking control systems ; Transition radiation ; Vibration</subject><ispartof>Journal of sound and vibration, 2021-02, Vol.492, p.115804, Article 115804</ispartof><rights>2020 The Authors</rights><rights>Copyright Elsevier Science Ltd. 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Two possible indicators of degradation in the supporting structure are identified, namely the wheel-rail contact force and the power/energy input by the vehicle. This paper analyses the influence of accounting for the interaction between the vehicle and the supporting structure on the contact force and on the power/energy input. To this end, a one-dimensional model is formulated, consisting of an infinite Euler-Bernoulli beam resting on a locally inhomogeneous Kelvin foundation, interacting with a moving loaded oscillator that has a nonlinear Hertzian spring. The solution is obtained using the Green’s-function method. To obtain the Green’s function of the inhomogeneous and infinite beam-foundation sub-system, the finite difference method is used for the spatial discretization and non-reflective boundary conditions are applied. Accounting for the interaction between the moving oscillator and the supporting structure generally leads to stronger wave radiation, caused by the variation of the vertical momentum of the moving mass. Results show that for relatively high velocity and small transition length, the maximum contact force as well as the energy input exhibit a significant increase compared to the moving constant load case. Furthermore, for relatively high velocities, the maximum contact force also increases significantly with increasing stiffness dissimilarity, findings which supplement the existing literature. 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subjects	Boundary conditions Contact force Degradation Euler-Bernoulli beams Eulers equations Finite difference method Green's functions Green’s function method Indicators Infinite system Inhomogeneous system Mathematical models Moving oscillator Non-reflective boundaries One dimensional models Railway networks Railway tracks Rolling contact Sound amplification Stiffness Tracking control systems Transition radiation Vibration
title	Transition radiation in an infinite one-dimensional structure interacting with a moving oscillator—the Green’s function method
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