Optimal single concave sliding device properties for isolated multi-span continuous deck bridges depending on the ground motion characteristics

Optimal single concave sliding device properties for isolated multi-span continuous deck bridges depending on the ground motion characteristics

The present study investigates the analysis of the optimal friction coefficient with respect to the seismic performance of isolated multi-span continuous deck bridges, equipped with single concave friction pendulum (FPS) isolators. A six-degree-of-freedom system is used to model the structural syste...

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Bibliographic Details
Published in:Soil dynamics and earthquake engineering (1984) Vol. 173; p. 108128
Main Authors: Castaldo, Paolo, Miceli, Elena
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-10-2023
Subjects:
Multi-span continuous deck bridges
Non-dimensional equations
Optimal friction coefficient
PGA/PGV ratio
Seismic isolation
Seismic performance
Multi-span continuous deck bridges
Seismic isolation
Non-dimensional equations
PGA/PGV ratio
Seismic performance
Optimal friction coefficient
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Summary:The present study investigates the analysis of the optimal friction coefficient with respect to the seismic performance of isolated multi-span continuous deck bridges, equipped with single concave friction pendulum (FPS) isolators. A six-degree-of-freedom system is used to model the structural system and the FPS friction property is described by means of a law that considers the dependency on the velocity. The equations of motions have been implemented in nondimensional form by considering the peak ground acceleration-to-velocity ratio (PGA/PGV) and the peak ground acceleration (PGA) as ground motion parameters for two different sets of seismic records: near-fault and far-field inputs. In addition, different bridge models are considered for various parameters (i.e., pier period, deck period, friction coefficient and mass of the structural system). The results show the effectiveness of the PGA/PGV ratio within the proposed nondimensionalization together with the existence of an optimum value of the friction coefficient that minimizes the nondimensional response of the pier. At the end, a linear regression expression is presented with the aim to compute the optimal value of the normalized friction coefficient as a function of the deck period and PGA/PGV ratio, which can be used in the preliminary phase to design the FPS bearings. Additionally, a multivariate non-linear regression expression is also provided to evaluate the pier response. •Seismic performance of multi-span continuous deck RC bridges with FPS devices.•Non-dimensionalization of motion equations is proposed including PGA/PGV ratio.•A wide parametric analysis for different structural properties is performed.•Far-field inputs with various PGA/PGV ratios and near-fault records are considered.•A linear expression between the optimal friction coefficient and Td/Tg ratio.
ISSN:0267-7261
1879-341X
DOI:10.1016/j.soildyn.2023.108128