This paper describes a numerical approach for the analysis of the seismic ground response and the dynamic soil-structure interaction accounting for the three components of an earthquake motion. The investigation was performed with reference to the case-history of Lotung (Tai-wan), where the seismic response of a nuclear power plant model as well as that of its founda-tion soil were measured during several earthquakes occurred at the site. The numerical anal-yses were carried out with the finite element code Plaxis, adopting for the soil the constitutive model Hardening Soil model with small strain stiffness. First, the model was validated with re-spect to the propagation of the vertical component of seismic motion, mainly associated to compressional seismic waves. Then fully 3D dynamic analyses were implemented for the sim-ulation of the strong motion event named LSST7. The good match between numerical predic-tions and monitoring data proved the effectiveness of the proposed approach.
A multi-directional numerical approach for the seismic ground response and dynamic soil-structure interaction analyses / di Lernia, A.; Amorosi, A.; Boldini, D.. - 4:(2019), pp. 2145-2152. (Intervento presentato al convegno 7th International conference on earthquake geotechnical engineering tenutosi a Rome; Italy).
A multi-directional numerical approach for the seismic ground response and dynamic soil-structure interaction analyses
Amorosi A.;Boldini D.
2019
Abstract
This paper describes a numerical approach for the analysis of the seismic ground response and the dynamic soil-structure interaction accounting for the three components of an earthquake motion. The investigation was performed with reference to the case-history of Lotung (Tai-wan), where the seismic response of a nuclear power plant model as well as that of its founda-tion soil were measured during several earthquakes occurred at the site. The numerical anal-yses were carried out with the finite element code Plaxis, adopting for the soil the constitutive model Hardening Soil model with small strain stiffness. First, the model was validated with re-spect to the propagation of the vertical component of seismic motion, mainly associated to compressional seismic waves. Then fully 3D dynamic analyses were implemented for the sim-ulation of the strong motion event named LSST7. The good match between numerical predic-tions and monitoring data proved the effectiveness of the proposed approach.File | Dimensione | Formato | |
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