Two methods are illustrated to calculate effectively the ground motion induced by constant speed moving loads. On one hand, the dynamic Betti-Rayleigh reciprocity theorem allows to take full advantage of the availability of Green’s functions for a homogeneous or a horizontally layered halfspace. On the other hand, the spectral element method allows to deal with complicated configurations, including dynamic soil-structure interaction, with an accuracy significantly higher than classical finite element or finite difference methods. Both Betti-Rayleigh and spectral element methods are considered in 3D. After validating both methods, the decay of peak ground motion with distance is analyzed as a function of load speed and frequency. For speeds lower than the Rayleigh wave velocity in the soil, the decay turns out to be much faster than for a stationary point load. This effect is studied in detail by an analytical approach and interpreted in terms of destructive interference. Finally, the previous analytical and numerical results are checked against the records obtained at Ath, Belgium, during a field experiment to study ground motion induced by high speed trains in soft soil conditions

Ground motion induced by train passage

PAOLUCCI, ROBERTO;
2006-01-01

Abstract

Two methods are illustrated to calculate effectively the ground motion induced by constant speed moving loads. On one hand, the dynamic Betti-Rayleigh reciprocity theorem allows to take full advantage of the availability of Green’s functions for a homogeneous or a horizontally layered halfspace. On the other hand, the spectral element method allows to deal with complicated configurations, including dynamic soil-structure interaction, with an accuracy significantly higher than classical finite element or finite difference methods. Both Betti-Rayleigh and spectral element methods are considered in 3D. After validating both methods, the decay of peak ground motion with distance is analyzed as a function of load speed and frequency. For speeds lower than the Rayleigh wave velocity in the soil, the decay turns out to be much faster than for a stationary point load. This effect is studied in detail by an analytical approach and interpreted in terms of destructive interference. Finally, the previous analytical and numerical results are checked against the records obtained at Ath, Belgium, during a field experiment to study ground motion induced by high speed trains in soft soil conditions
2006
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11311/552616
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