Prediction and mitigation of train-induced vibrations of over-track buildings on a metro depot: Field measurement and numerical simulation

Wang, Siqi; Cao, Zhigang; Xu, Yifei; Xiao, Zheng; Yuan, Zonghao; Cai, Yuanqiang; Changfei, Gou

doi:10.1177/10775463221135396

Cited by 5 publications

(1 citation statement)

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“…Analytical methods are based on the pipe-in-pipe model [6], the transfer matrix method [7], the semi-analytical method [8] or others for modelling soiltunnel coupling in elastic semi-infinite space or full space, which have good computational efficiency. Numerical methods include the finite element model [9], the 2.5-dimensional finite element model [10], the finite element-infinite element model [11] and the boundary element model [12], which allow for more detailed modelling. In some cases, symmetry is used to reduce the model size and then improve computational efficiency.…”

Section: Introductionmentioning

confidence: 99%

Analysis of Vibration Responses Induced by Metro Operations Using a Probabilistic Method

Wu,

Li,

Liu

et al. 2024

Symmetry

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The environmental vibrations of tunnels and soil caused by metro operations is one of the most important issues in the field of environmental geotechnical engineering. Recent studies in metro-induced vibrations have revealed significant uncertainties in the vibration responses of tunnels and the surrounding soil. A two-step method of obtaining train loads considering uncertainty was introduced. The first step was to obtain the train loads via an inverse model based on measurements, and the second step was to quantify the uncertainty of train loads based on complex principal component analysis. A portion of a tunnel of the Beijing metro was selected as the object of study, where the vertical accelerations on the rail and on the tunnel wall were measured under different train speeds of 35, 45 and 55 km/h. Inputting the train loads based on the measured rail accelerations into an axisymmetric numerical model, established using ANSYS, the vibration responses of the tunnel wall in a probabilistic framework were calculated and were compared with the measured results. By using an accuracy index that considers both calculation bias and uncertainty, the accuracy of the calculated vibration response was quantitatively evaluated. It can be concluded that the calculated vibration response can reflect the actual vibration level and uncertainty of the tunnel wall. The accuracies of the calculated results under different speeds were generally high while showing a slight difference in amplitude.

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