Analysis of Seismic Isolation Performance of X-Shaped Rubber Bearings (XRBs)
Abstract
:1. Introduction
2. Introduction of XRB’s Features
2.1. Design Features
2.2. Horizontal Mechanical Properties of XRB
3. Finite Element Modeling of Seismically Isolated Buildings
3.1. Design of Isolation Layer
- (1)
- The total height of the laminated rubber part of the steel plate is 85 mm;
- (2)
- The and are 17 mm and 34 mm, respectively;
- (3)
- The minimum diameter () of the bearing is 250 mm, and the large diameter () of the bearing is 370 mm;
- (4)
- The compressive stress at the minimum cross-section of the bearing is 8.50 MPa.
3.2. Structural Parameters and Finite Element Model
4. Seismic Analysis of Numerical Model
4.1. Input of Ground Motion
4.2. Analysis Results
4.2.1. Displacement Response
4.2.2. Velocity Response
4.2.3. Acceleration Response
4.3. Discussion of Results
5. Summary and Conclusions
- (1)
- The limit value of horizontal shear deformation of XRB is greater than that of TRB, which can effectively control the bearing failure under strong earthquake. XRB can effectively reduce the horizontal earthquake acceleration of the structure when the structure is subjected to a 2–3% PE earthquake with a 50-year event and a 1‱ PE earthquake with a one-year event, and has good horizontal seismic isolation performance, which can meet the need for horizontal isolation. At the same time, XRB can prevent the failure of the structure due to the over-limit deformation of the seismic isolation layer and improve the overall seismic safety of the isolated structure.
- (2)
- When the earthquake intensity exceeds the structural design ground motion intensity (for example, 1‱ PE in a one-year event), the horizontal displacement of the building will exceed the limit value of compressional shear deformation of TRB, leading to failure of the isolation layer and the collapse of the whole structure. Thus, it is necessary for the seismically isolated building to pay attention to the displacement of the isolation layer to avoid the displacement response of the earthquake exceeding the deformation limit value of TRB.
- (3)
- Although the RWP of the building can effectively prevent the deformation of the isolation layer from exceeding the limit, the superstructure will collide with the RWPs when the horizontal displacement of the isolation bearing reaches the limit displacement. When the superstructure possesses a large impulse, its collision with the RWP leads to a significant increase in collision damage and acceleration at the bottom of the superstructure. Therefore, when the bearing displacement exceeds the limit value, the seismic isolation structure with RWP can prevent the failure of the seismic isolation bearing, but it may lead to structural damage and may reduce the overall seismic isolation performance.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Parameter | Value | Unit |
---|---|---|
Elastic modulus of concrete | 30,000 | Mpa |
Axial compressive strength of concrete | 20.1 | Mpa |
Elastic modulus of reinforcement | 200,000 | Mpa |
Yield strength of reinforcement | 335 | Mpa |
1st NP of model using XRBs | 1.80 | s |
1st NP of model using TRBs | 1.96 | s |
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Wu, D.; Lin, J.; Xiong, Y. Analysis of Seismic Isolation Performance of X-Shaped Rubber Bearings (XRBs). Buildings 2022, 12, 1102. https://doi.org/10.3390/buildings12081102
Wu D, Lin J, Xiong Y. Analysis of Seismic Isolation Performance of X-Shaped Rubber Bearings (XRBs). Buildings. 2022; 12(8):1102. https://doi.org/10.3390/buildings12081102
Chicago/Turabian StyleWu, Di, Jingtian Lin, and Yan Xiong. 2022. "Analysis of Seismic Isolation Performance of X-Shaped Rubber Bearings (XRBs)" Buildings 12, no. 8: 1102. https://doi.org/10.3390/buildings12081102
APA StyleWu, D., Lin, J., & Xiong, Y. (2022). Analysis of Seismic Isolation Performance of X-Shaped Rubber Bearings (XRBs). Buildings, 12(8), 1102. https://doi.org/10.3390/buildings12081102