Influence of different design parameters on the seismic performance of partially grouted masonry shear walls

Reinforced concrete (RC) walls are extensively used in high-rise buildings to resist lateral loads, while ensuring an adequate level of ductility. Durability problems, including corrosion of conventional steel reinforcements, necessitate exploring alternative types of reinforcement. The use of glass fiber reinforced polymer (FRP) bars is a potential solution. However, these bars cannot be used in seismic applications because of their brittleness and inability to dissipate seismic energy. Superelastic shape memory alloy (SMA) is a corrosion-free material with high ductility and unique self-centering ability. Its high cost is a major barrier to use in construction projects. The clear advantage of utilizing both SMA and FRP to achieve durable self-centering structures has motivated the development of a composite SMA-FRP bar. This paper investigates the hybrid use of FRP bars and either SMA bars or composite SMA-FRP in concrete shear walls. An extensive parametric study was conducted to study the effect of different design parameters on the lateral performance of hybrid RC walls. The seismic behavior of the hybrid walls was then examined. The hybrid walls not only solved the durability problem but also significantly improved the seismic performance.

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Numerical Analysis on the Effect of Vital Design Parameters on the Seismic Performance of Shear Walls with Horizontal Ring Connection

IOP Conference Series Earth and Environmental Science ◽

10.1088/1755-1315/719/4/042016 ◽

2021 ◽

Vol 719 (4) ◽

pp. 042016

Author(s):

Jian Zhou ◽

Tao Zhang ◽

Liming Li ◽

Zhipeng Guo ◽

Qiancheng Shi

Keyword(s):

Numerical Analysis ◽

Seismic Performance ◽

Shear Walls ◽

Design Parameters

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Seismic performance of precast shear walls prestressed via post-tensioned high strength bars placed inside grouted corrugated pipes

Engineering Structures ◽

10.1016/j.engstruct.2021.112153 ◽

2021 ◽

Vol 237 ◽

pp. 112153

Author(s):

Qing Zhi ◽

Liqun Kang ◽

Lu Jia ◽

Jingang Xiong ◽

Zhengxing Guo

Keyword(s):

Seismic Performance ◽

Shear Walls ◽

High Strength ◽

Post Tensioned

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Experimental Investigation into the Seismic Performance of Prefabricated Reinforced Masonry Shear Walls with Vertical Joint Connections

Applied Sciences ◽

10.3390/app11104421 ◽

2021 ◽

Vol 11 (10) ◽

pp. 4421

Author(s):

Zhiming Zhang ◽

Fenglai Wang

Keyword(s):

Seismic Performance ◽

Cross Sections ◽

Shear Walls ◽

Construction Method ◽

Shear Capacity ◽

Initial Stiffness ◽

Equivalent Viscous Damping ◽

Displacement Ductility ◽

Reinforced Masonry ◽

Cracking Performance

In this study, four single-story reinforced masonry shear walls (RMSWs) (two prefabricated and two cast-in-place) under reversed cyclic loading were tested to evaluate their seismic performance. The aim of the study was to evaluate the shear behavior of RMSWs with flanges at the wall ends as well as the effect of construction method. The test results showed that all specimens had a similar failure mode with diagonal cracking. However, the crack distribution was strongly influenced by the construction method. The lateral capacity of the prefabricated walls was 12% and 27% higher than that of the corresponding cast-in-place walls with respect to the rectangular and T-shaped cross sections. The prefabricated walls showed better post-cracking performance than did the cast-in-place wall. The secant stiffness of all the walls decreased rapidly to approximately 63% of the initial stiffness when the first major diagonal crack was observed. The idealized equivalent elastic-plastic system showed that the prefabricated walls had a greater displacement ductility of 3.2–4.8 than that of the cast-in-place walls with a displacement ductility value of 2.3–2.7. This proved that the vertical joints in prefabricated RMSWs enhanced the seismic performance of walls in shear capacity and ductility. In addition, the equivalent viscous damping of the specimens ranged from 0.13 to 0.26 for prefabricated and cast-in-place walls, respectively.

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Numerical modeling to predict seismic performance of the post-tensioned self-centering concrete shear walls

Bulletin of Earthquake Engineering ◽

10.1007/s10518-021-01309-4 ◽

2022 ◽

Author(s):

Yang Liu ◽

Wei Zhou

Keyword(s):

Numerical Modeling ◽

Seismic Performance ◽

Shear Walls ◽

Post Tensioned

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Estimation of Seismic Energy Dissipation for Steel Slit Shear Walls Considering Out-of-Plane Buckling

International Journal of Structural Stability and Dynamics ◽

10.1142/s0219455422500298 ◽

2021 ◽

Author(s):

Yiming Ma ◽

Liusheng He ◽

Ming Li

Keyword(s):

Energy Dissipation ◽

Shear Walls ◽

Seismic Energy ◽

Thickness Ratio ◽

Design Parameters ◽

Test Results ◽

Loading Test ◽

Aspect Ratios ◽

Out Of Plane ◽

Energy Dissipation Capacity

Steel slit shear walls (SSSWs), made by cutting slits in steel plates, are increasingly adopted in seismic design of buildings for energy dissipation. This paper estimates the seismic energy dissipation capacity of SSSWs considering out-of-plane buckling. In the experimental study, three SSSW specimens were designed with different width-thickness ratios and aspect ratios and tested under quasi-static cyclic loading. Test results showed that the width-thickness ratio of the links dominated the occurrence of out-of-plane buckling, which produced pinching in the hysteresis and thus reduced the energy dissipation capacity. Out-of-plane buckling occurred earlier for the links with a larger width-thickness ratio, and vice versa. Refined finite element model was built for the SSSW specimens, and validated by the test results. The concept of average pinching parameter was proposed to quantify the degree of pinching in the hysteresis. Through the parametric analysis, an equation was derived to estimate the average pinching parameter of the SSSWs with different design parameters. A new method for estimating the energy dissipation of the SSSWs considering out-of-plane buckling was proposed, by which the predicted energy dissipation agreed well with the test results.

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Effects of Brace Stiffness and Nonlinearity of Viscous Dampers on Seismic Performance of Structures

International Journal of Structural Stability and Dynamics ◽

10.1142/s0219455421501881 ◽

2021 ◽

pp. 2150188

Author(s):

Siyuan Li ◽

Yung-Tsang Chen ◽

Y. H. Chai ◽

Bo Li

Keyword(s):

Seismic Performance ◽

Structural Performance ◽

Design Parameters ◽

Viscous Dampers ◽

Story Structure ◽

Design Efficiency ◽

Time Stepping ◽

Seismic Hazard Mitigation ◽

Method Effects ◽

Supplemental Dampers

In the applications of supplemental dampers for seismic hazard mitigation, the supporting braces for the dampers are considered an important component for ensuring an efficient energy dissipation in the structure. Despite their importance, studies on the effects of the brace stiffness and the velocity exponent in the case of nonlinear viscous dampers are rather limited. In this paper, a numerical time-stepping method is developed for computing the seismic response of the structure with supporting braces and nonlinear viscous dampers. Using the proposed method, effects of the parameters of the nonlinear damper-brace systems are investigated, using first a single-story structure, followed by multi-story buildings. Results indicated that the design parameters for the dampers and supporting braces may be combined in numerous ways to satisfy a given set of structural performance objectives, but the brace stiffness can be minimized to achieve design efficiency in the range of velocity exponent commonly used for seismic applications of nonlinear viscous dampers. Results also indicated that for a set brace stiffness, if the dampers are optimally designed, the velocity exponent has an insignificant effect on the structural seismic performance objectives considered in this paper.

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