Study of curved surface sliding isolated structure with multiple bearings

Earthquake is one of the most devastating natural disasters in the world. Elastomeric bearings are costly for the low-rise residential buildings of developing countries. Thus, it is necessary to research low-cost and highly efficient frictional bearings. A dynamic model of Curved Surface Sliding Iso...

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Bibliographic Details
Published in:Soil dynamics and earthquake engineering (1984) 2021-08, Vol.147, p.106814, Article 106814
Main Authors: Wang, Changhong, Han, Shijie, Hu, Baolin, He, Wenfu, Keleta, Yonas
Format: Article
Language:English
Subjects:
Bearings
Buildings
Coefficient of friction
Damping ratio
Design parameters
Developing countries
Displacement
Dynamic models
Earthquakes
Elastomers
Friction
Frictional sliding bearing
LDCs
Lift-off force
Mathematical models
Natural disasters
Numerical simulations
Parameter identification
Radius of curvature
Residential areas
Residential buildings
Seismic activity
Seismic isolation
Seismic isolation layer
Sensitivity analysis
Shake table tests
Shaking table test
Sliding
Superstructures
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Summary:Earthquake is one of the most devastating natural disasters in the world. Elastomeric bearings are costly for the low-rise residential buildings of developing countries. Thus, it is necessary to research low-cost and highly efficient frictional bearings. A dynamic model of Curved Surface Sliding Isolated Structure (CSSIS) will be studied under horizontal earthquakes. Theoretical derivation concentrates on identifying the design parameters that affect the accelerations, displacements and lift-off forces of seismic isolation bearings. Key factors consist of radius of curvature, coefficient of friction, and damping ratio of the superstructure. Sensitivity analysis is performed by the numerical simulation, followed by comparing the results of the analysis with the shaking table tests. As the curvature radius increases, the displacements of the superstructure enlarge, the accelerations remain stable and the reaction forces of seismic isolation bearings decrease simultaneously. On the other hand, if the friction coefficient increases, the displacements of the superstructure decreases, but the accelerations of the superstructure and the reaction forces get enlarged. Results prove that CSSIS can effectively control the sliding displacement, superstructure recovery and lift-off forces of seismic isolation layer. The current finding will have a broad application of low-rise residential buildings, especially in the developing countries. •Curved surface sliding isolated structure with multiple frictional bearings.•Lift-off forces of frictional sliding bearings can be well controlled by design parameters.•Curved surface sliding isolated structure has a robust capacity of seismic resistance.
ISSN:0267-7261
1879-341X
DOI:10.1016/j.soildyn.2021.106814