Integral abutment bridges are characterised by a monolithic connection between the deck and the abutments. Because of this connection, the seismic behaviour of the entire structure tends to be controlled by its interaction with the surrounding soil, and especially with the approach embankments. To date, methods for the seismic design of this type of bridges are still characterised by substantial uncertainties, mostly because of insufficient understanding of the dynamic response of the soil-structure system. This paper provides a contribution to the interpretation of the seismic behaviour of integral abutment bridges, focusing on a single-span structural scheme that has been receiving significant attention in recent years. The dynamic interaction between the bridge and the soil is studied with global numerical models of the soil-bridge system developed in OpenSees and subjected to a variety of ground motions. The results of the dynamic simulations, interpreted also with the aid of a modal analysis of the system, are used to develop and finally validate a simplified design procedure. This procedure is based on the capacity spectrum method, aimed at evaluating the maximum deformation and internal forces in the structure produced by the longitudinal component of the seismic motion that typically dominates the design of integral bridges.

A non-linear static analysis for the seismic design of single-span integral abutment bridges / Gallese, Domenico; Gorini, DAVIDE NOÈ; Callisto, Luigi. - In: GEOTECHNIQUE. - ISSN 0016-8505. - (2024), pp. 1-15. [10.1680/jgeot.22.00229]

A non-linear static analysis for the seismic design of single-span integral abutment bridges

Gallese, Domenico;CALLISTO, LUIGI
2024

Abstract

Integral abutment bridges are characterised by a monolithic connection between the deck and the abutments. Because of this connection, the seismic behaviour of the entire structure tends to be controlled by its interaction with the surrounding soil, and especially with the approach embankments. To date, methods for the seismic design of this type of bridges are still characterised by substantial uncertainties, mostly because of insufficient understanding of the dynamic response of the soil-structure system. This paper provides a contribution to the interpretation of the seismic behaviour of integral abutment bridges, focusing on a single-span structural scheme that has been receiving significant attention in recent years. The dynamic interaction between the bridge and the soil is studied with global numerical models of the soil-bridge system developed in OpenSees and subjected to a variety of ground motions. The results of the dynamic simulations, interpreted also with the aid of a modal analysis of the system, are used to develop and finally validate a simplified design procedure. This procedure is based on the capacity spectrum method, aimed at evaluating the maximum deformation and internal forces in the structure produced by the longitudinal component of the seismic motion that typically dominates the design of integral bridges.
2024
design approach; foundations; integral abutment bridges; dynamic soil-structure interaction; modal analysis; non-linear static analysis; numerical modelling; OpenSees; seismic engineering
01 Pubblicazione su rivista::01a Articolo in rivista
A non-linear static analysis for the seismic design of single-span integral abutment bridges / Gallese, Domenico; Gorini, DAVIDE NOÈ; Callisto, Luigi. - In: GEOTECHNIQUE. - ISSN 0016-8505. - (2024), pp. 1-15. [10.1680/jgeot.22.00229]
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11573/1727741
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