Seismic behavior of frost-damaged squat RC shear walls under artificial climate environment: a further experimental research

Rong, Xian‒Liang; Zheng, Shansuo; Zhang, Yixin; Li, Dong; Liu, Huan; Dai, Kuang-Yu

doi:10.1007/s43452-020-00081-7

Cited by 19 publications

(4 citation statements)

References 32 publications

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“…(3) When the pier top load exceeds the peak load P m , the RC pier is in the degradation stage, and the pier top load and unloading stiffness gradually decrease. The loading path is loaded according to 8-16 (12)(13)(14)(15)(16)(17)(18)(19). The loading path is loaded according to the degradation stiffness K 3 and calculated according to Equation (26).…”

Section: Determination Of Unloading Stiffnessmentioning

confidence: 99%

“…The proposed restoring force model was suitable for the study of the seismic problem of RC piers in a freshwater environment. Zheng et al [15][16][17] established the restoring force model of (low shear span ratio) shear walls after freshwater freeze-thaw cycles, and the numerical analysis was carried out according to the relevant experiments. The effectiveness of the proposed model was verified by comparing the results of hysteresis curves and cumulative energy consumption between the experiment and numerical calculations.…”

Section: Introductionmentioning

confidence: 99%

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Restoring Force Model of Precast Segmental Reinforced Concrete Piers after Seawater Freeze–Thaw Cycles

et al. 2022

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Precast segmental reinforced concrete (RC) piers have been widely used in the construction of offshore bridges to speed up construction. Offshore bridges in cold regions are inevitably affected by the seawater freeze–thaw cycles under the periodic movement of tides, which could reduce the mechanical property of RC piers. Based on the low cyclic loading test on 12 specimens with different seawater freeze–thaw cycles, axial compression ratio, diameters of longitudinal reinforcement, and stirrup spacing, the hysteresis characteristics of precast segmental RC piers were analyzed. The test results show that the peak load decreased by 11%, while the peak displacement increased by 40% after 125 seawater freeze–thaw cycles. The hysteresis curves became fuller and the residual displacement became smaller with the accumulation of freeze–thaw damage. In the same 125 freeze–thaw cycles, the peak load increased by 15% and 27% while increasing the axial compression ratio and the longitudinal reinforcement diameter. Combined with the regression analysis of the experimental results, the restoring force model of RC piers considering the seawater freeze–thaw damage and design parameters was established, and the calculation method of each characteristic point in the model was given. The deviation values of flexural capacity are not more than 6.5%, and the deviation values of peak displacement are not more than 12%. The restoring force model determined in this paper could provide a reference for seismic response analysis of offshore bridges in cold regions.

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Section: Determination Of Unloading Stiffnessmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Restoring Force Model of Precast Segmental Reinforced Concrete Piers after Seawater Freeze–Thaw Cycles

et al. 2022

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“…The accuracy of the numerical simulation method was verified by comparing it with the experimental results. Zhang et al [18][19][20] conducted a numerical simulation of the shear wall and RC columns after freshwater freeze-thaw cycles using the fiber beam element method. Based on the pull-out test of reinforced concrete specimens, the degradation law of bond strength was established, which could consider the distribution of freeze-thaw damage.…”

Section: Introductionmentioning

confidence: 99%

Numerical Simulation of Reinforced Concrete Piers after Seawater Freeze–Thaw Cycles

et al. 2022

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The reinforced concrete (RC) piers of offshore bridges inevitably experience seawater freeze–thaw cycles due to the periodic movement of tides in cold climates. The damage caused by seawater freeze–thaw cycles will reduce the durability and mechanical properties of concrete, and then affect the seismic performance of RC piers. The method of seismic performance analysis on RC piers by numerical simulation is gradually emerging because the process of the conventional experiment is relatively complicated, and the heterogeneity and degradation of concrete after seawater freeze–thaw cycles should be considered. In this study, the method of meso-element equivalent and layered modeling was used to simulate a low cyclic loading test on an RC pier after seawater freeze–thaw cycles with ABAQUS software. The numerical simulation results were compared with the experimental results; the deviation value of peak load was not more than 6%, and the deviation value of peak displacement was not more than 10%. The result of the numerical simulation matched well with the experimental results, and the influence of different parameters was analyzed through the practical method of numerical simulation. It can be determined that the peak load decreased by 11%, while the peak displacement increased by 40% after 125 seawater freeze–thaw cycles. In the same 125 freeze–thaw cycles, the peak load increased by 15% and 27% while the axial compression ratio and the longitudinal reinforcement diameter increased. As the stirrup spacing of specimens decreased, the peak load remained unchanged, but the ductility coefficient of the specimens increased by 20%.

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“…Therefore, it can be concluded that the Bouc-Wen model, because of its limited number of parameters, provides the specific shape of the hysteresis loop given in Figure 1. However, the range of hysteresis loops observed in materials is much more diverse than the one provided by the Bouc-Wen model, since this range includes asymmetry of the loop, 13 pinching, 14,15 degrading, 16 or multiple loops. 17 This is why various authors proposed modifications of the Bouc-Wen model by incorporating more terms and parameters into the differential equation; see the survey paper.…”

Section: Introduction and Problem Statementmentioning

confidence: 99%

A data‐driven hysteresis model

Ikhouane

2022

Structural Contr & Hlth

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Summary Hysteresis is a special type of behavior encountered in various fields of science and engineering. In civil engineering and smart structures, the Bouc–Wen model has been used extensively to represent materials with hysteresis. This model consists of a first‐order scalar nonlinear differential equation that includes a few parameters for the standard version of the model and a large number of parameters for its extended versions. This said, whilst the properties of the standard Bouc–Wen model have been studied mathematically, the extensions of the model have only been studied using numerical simulations so that there are no mathematical formulas for the hysteresis loops that these extended models generate. Motivated by this issue, I propose a new model of hysteresis that does not include a finite number of parameters but rather includes several functions that are updated using experimental data. This data‐driven model is able to produce loops or multiple loops with asymmetry, pinching, and degrading; and mathematical formulas for the hysteresis loops that the model generates are available.

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Seismic behavior of frost-damaged squat RC shear walls under artificial climate environment: a further experimental research

Cited by 19 publications

References 32 publications

Restoring Force Model of Precast Segmental Reinforced Concrete Piers after Seawater Freeze–Thaw Cycles

Restoring Force Model of Precast Segmental Reinforced Concrete Piers after Seawater Freeze–Thaw Cycles

Numerical Simulation of Reinforced Concrete Piers after Seawater Freeze–Thaw Cycles

A data‐driven hysteresis model

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