Numerical Investigation on the Hysteretic Performance of Self-Centering Precast Steel–Concrete Hybrid Frame

To improve the construction performance and seismic resilience of precast reinforced-concrete frame structures, an innovative self-centering precast steel–concrete hybrid frame has been proposed and subjected to cyclic loading tests. In this paper, a comprehensive numerical analysis was conducted to...

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Bibliographic Details
Published in:Buildings (Basel) 2024-10, Vol.14 (10), p.3202
Main Authors: Feng, Shiqiang, Yang, Yong, Xue, Yicong, Yu, Yunlong
Format: Article
Language:English
Subjects:
Bearing strength
Carrying capacity
Columns (structural)
Comparative analysis
Concrete
Cyclic loads
Deformation
Design parameters
Earthquake construction
Earthquake resistance
Earthquakes
Energy dissipation
Finite element method
Frame structures
Friction
Hysteresis
hysteretic performance
Investigations
Load carrying capacity
Mathematical analysis
Mathematical models
numerical analyses
Numerical analysis
Numerical models
post-tensioned tendons
Post-tensioning
Precast concrete
Reinforced concrete
Reinforcing steels
Seismic engineering
Seismic response
self-centering precast steel–concrete hybrid frame
Simulation
Simulation methods
Sliding friction
Steel
Stiffness
web friction device
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Summary:To improve the construction performance and seismic resilience of precast reinforced-concrete frame structures, an innovative self-centering precast steel–concrete hybrid frame has been proposed and subjected to cyclic loading tests. In this paper, a comprehensive numerical analysis was conducted to further investigate the frame’s hysteretic behavior. Initially, a numerical model was developed using the finite element software OpenSees. Numerical analyses of two frame specimens were conducted, demonstrating good agreement between the numerical and experimental hysteretic characteristics, thus validating the model’s accuracy. Subsequently, based on the numerical simulations, a quantitative comparison of hysteretic performance between a novel frame and a traditional reinforced-concrete frame of the same scale was performed. While the proposed frame exhibited slightly lower initial stiffness and energy dissipation capacity than the traditional frame, it outperformed in terms of load-carrying capacity and self-centering ability. Finally, parametric analyses were carried out to assess the influence of various design parameters on the hysteretic performance, including friction force in the web frictions devices, initial post-tensioned force of the prefabricated steel–concrete hybrid beams, the steel arm length, and the column longitudinal reinforcement ratio. The results showed that increases in these four parameters improved the load-carrying capacity and initial stiffness of the proposed frame. Additionally, an increase in the friction force, steel arm length, or column longitudinal reinforcement ratio enhanced the frame’s energy dissipation capacity, while an increase in the initial post-tensioned force or a decrease in the friction force enhanced the frame’s self-centering capacity.
ISSN:2075-5309
2075-5309
DOI:10.3390/buildings14103202