Abstract
Resonance problems encountered in vehicle-bridge interaction (VBI) have attracted widespread concern over the past decades. Due to system random characteristics, the prediction of resonant speeds and responses will become more complicated. To this end, this study presents stochastic analysis on the resonance of railway trains moving over a series of simply supported bridges with consideration of the randomness of system parameters. A train-slab track-bridge (TSB) vertically coupled dynamics model is established following the basic principle of vehicle-track-coupled dynamics. The railway train is composed of multiple vehicles, and each of them is built by seven rigid parts assigned with a total of 10 degrees of freedom. The rail, track slab, and bridge are considered as Euler–Bernoulli beams, and the vibration equations of which are established by the modal superposition method (MSM). Except for the nonlinear wheel-rail interaction based on the Hertz contact theory, the other coupling relations between each subsystem are assumed to be linear elastic. The number theory method is employed to obtain the representative sample point sets of the random parameters, and the flow trajectories of probabilities for the TSB dynamics system are captured by a probability density evolution method (PDEM). Numerical results indicate that the maximum bridge and vehicle responses are mainly dominated by the primary train-induced resonant speed; the last vehicle of a train will be more seriously excited when the bridges are set in resonance by the train; the resonant speeds and responses are rather sensitive to the system randomness, and the possible maximum amplitudes predicted by the PDEM are significantly underestimated by the traditional deterministic method; optimized parameters of the TSB system are preliminary obtained based on the representative point sets and imposed screening conditions.
Highlights
Railway bridges account for a large proportion of the substructures in railway lines due to safety, comfort, and mitigation of noise pollution
Based on the principle of probability conservation, an probability density evolution method (PDEM) is applied to capture the flow trajectories of probabilities for the TSB dynamics system. is section is divided into two parts: one is the determination of the representative point sets of random parameters of the TSB system, and the other is the solution to the random dynamic responses of the TSB system based on the PDEM
With the train speed varying from 300 km/h to 400 km/h, the maximum bridge acceleration is found to be 0.349 g at v 380 km/h, and the maximum car body acceleration is found to be 0.066 g at v 400 km/h. e possible maximum amplitudes predicted by the PDEM are significantly underestimated by the traditional deterministic method
Summary
Railway bridges account for a large proportion of the substructures in railway lines due to safety, comfort, and mitigation of noise pollution. E numerical examples indicate that the vertical acceleration induced by pitching resonance dominates the peak response of the train and neglecting the effect of may underestimate slightly the beam response in the high-speed range and less slightly the moving vehicle response. A scrutiny of the previous studies on the resonance problem induced by VBI indicates that most of them were performed using the deterministic dynamic analysis method, and random characteristics of the train and bridge systems may have great influence on the resonance and dynamic responses. E main purpose of this study was to provide a better understanding of the resonance of railway trains moving over supported bridges considering the randomness of system parameters, and a preliminary discussion on an optimal matching relationship of TSB parameters is presented.
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