Enhancing Friction Pendulum Isolation Systems Using Passive and Semi-Active Dampers

Christian A Barrera-Vargas,Jaime H García-Palacios,Iván M Díaz,José M Soria

doi:10.3390/app10165621

Christian A Barrera-Vargas, Jaime H García-Palacios + Show 2 more

Open Access

https://doi.org/10.3390/app10165621

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Journal: Applied sciences	Publication Date: Aug 13, 2020
Citations: 9	License type: CC BY 4.0

Affiliation: Universidad Politécnica de Madrid

Abstract

Friction pendulum systems (FPSs) are a common solution for isolating civil engineering structures under ground movements. The result is a base-isolated structure in which the base exhibits low shear stiffness in such a way that the input energy of the earthquake is concentrated and dissipated into it, leaving the superstructure free of damage. As a consequence, large displacements of the FPS may be demanded depending on the earthquake intensity and the fundamental period of the FPS. To accommodate these displacements, large-size isolators with high friction coefficients are usually required. However, the FPS will then exhibit poor re-centering capacity and the risk of future shocks will increase due to previous residual displacements, especially for low-intensity earthquakes. An alternative solution is to include a semi-active damper to the FPS, keeping the friction coefficient low and achieving both, limited base displacement under high-intensity earthquakes and good re-centering capacity under low-intensity ones. Thus, this work presents a design methodology for base isolators formed by an FPS with a damper added. The design methodology is applied to an FPS with a passive damper and to an FPS with a semi-active damper. Two ON-OFF control strategies are studied: (i) a fairly simple phase control, and (ii), a mechanical energy-predictive based algorithm. The advantages of semi-active FPSs with low friction coefficients with respect to FPS with high friction coefficients are demonstrated. The results with the designed semi-active FPS are compared with the single FPS and the FPS with a passive damper. Finally, the use of semi-active FPS allows us to enhance the FPS performance as the isolator size can be reduced while keeping the capacity to cope with low and high-intensity earthquakes without residual displacements.

Highlights

Base isolation systems are implemented to mitigate the damage and minimize the risk of collapse of structures due to earthquake vibrations
This paper presents a two-step design methodology for an friction pendulum systems (FPSs) with a passive or semi-active damper
When the earthquake intensity is reduced, the high-friction-coefficient FPS tends to behave as the non-isolated structure, that is, it is unable to filter out the input ground motion

Summary

Introduction

Base isolation systems are implemented to mitigate the damage and minimize the risk of collapse of structures due to earthquake vibrations. The isolators are usually designed to move the first-mode period of the structure out of the maximum acceleration of the design response spectrum through a higher fundamental period of the isolator system. This concept has given satisfactory results, allowing the development of different types of isolators, with linear and/or nonlinear behavior such as lead-rubber bearings, high damping rubber bearings, and friction pendulum systems (FPSs), these being the most common ones [3].

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