Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Seismic Analysis of Pile-Soil Interaction in Liquefiable Soils via Gap Elements
Recently, design of pile foundation in liquefiable soil has drawn considerable attention because of extensive damage to marine structures, such as bridges and wharves, which occurred in earthquakes. One of the major factors which governs the safe design of pile foundations is the soil-pile interaction, which itself can be affected by nonlinearities such as pile yielding, gapping, and soil recompression. After running a fully coupled dynamic analysis in a finite difference program (FLAC-2D), gapping effects on pile-soil interaction are evaluated here. Pore pressure generation, liquefaction and energy dissipation are captured in a developed numerical model. The model and the process of computation have been verified with centrifuge test data. A number of analyses are conducted in two conditions - with and without gap formation - for a wide range of frequencies to evaluate the effect of interface nonlinearities. It is observed that consideration of gapping may result in striking changes in pile internal forces and critical sections as well as excess pore water pressures in the vicinity of a pile.
Seismic Analysis of Pile-Soil Interaction in Liquefiable Soils via Gap Elements
Recently, design of pile foundation in liquefiable soil has drawn considerable attention because of extensive damage to marine structures, such as bridges and wharves, which occurred in earthquakes. One of the major factors which governs the safe design of pile foundations is the soil-pile interaction, which itself can be affected by nonlinearities such as pile yielding, gapping, and soil recompression. After running a fully coupled dynamic analysis in a finite difference program (FLAC-2D), gapping effects on pile-soil interaction are evaluated here. Pore pressure generation, liquefaction and energy dissipation are captured in a developed numerical model. The model and the process of computation have been verified with centrifuge test data. A number of analyses are conducted in two conditions - with and without gap formation - for a wide range of frequencies to evaluate the effect of interface nonlinearities. It is observed that consideration of gapping may result in striking changes in pile internal forces and critical sections as well as excess pore water pressures in the vicinity of a pile.
Seismic Analysis of Pile-Soil Interaction in Liquefiable Soils via Gap Elements
Ghasemi, Golara (Autor:in) / Barari, Amin (Autor:in) / Choobbasti, Asskar Janalizadeh (Autor:in)
Geo-Shanghai 2014 ; 2014 ; Shanghai, China
05.05.2014
Aufsatz (Konferenz)
Elektronische Ressource
Englisch
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