Abstract
It is very important to investigate the effects of the seismic performance of corrosion-damaged reinforced concrete (RC) members, in terms of their strength and lateral deformability, on the seismic performance of entire building systems. Such investigation allows accurate evaluation of the seismic performance of RC structures with corroded members, including beams and columns. However, current techniques for evaluating the seismic performance of existing RC structures do not take the effects of deterioration (including the corrosion of reinforcing bars) on the performance of RC members into account. The main objective of this research is to propose a practical methodology for evaluating the seismic performance of RC buildings with corrosion-damaged members. We extrapolate a structural performance degradation factor from the strength-deformation capability of corroded members to allow direct quantitative evaluation of their seismic performance. In this study, as a first step toward achieving this goal, we experimentally investigated the effect of reinforcing bar corrosion on the behavior of RC beams and the structural performance degradation factor. Our analysis was based on the strength-deformation capabilities of corrosion-damaged beams. We also propose a relationship between the half-cell potential of corroded reinforcing bars and the structural performance degradation behavior of RC beams. Our results indicate that there is a relatively strong correlation between the performance degradation factor and the average potential difference, with coefficients of determination (R2) of the flexural and shear beams of 0.78 and 0.91, respectively. The potential difference, which was measured using the half-cell measurement method, can serve as one of the indicators of relative structural degradation, but we must ensure that the environmental measurement conditions are held constant.
Highlights
Reinforced concrete (RC) structures are the most common structural systems in modern society, due to their low construction and maintenance costs and high durability compared to other types of structures. e structural performance of RC structures, deteriorates over time for various reasons, such as changes in the environmental conditions, design load, and material properties, as well as structural design errors and defective construction
We experimentally investigated the effect of the corrosion of reinforcing bars on the flexural and shear behaviors of RC beams and proposed a relationship between the half-cell potential of corroded reinforcing bars and structural performance degradation behavior of RC beams. e following conclusions can be drawn from our experimental results: (1) e flexural and shear behaviors of the control beams were generally similar to the typical behaviors of underreinforced beams. e shear and flexural beams, corroded to varying degrees among specimens, exhibited similar failure patterns to the control beam
(2) Based on the test results on the flexural behavior of beams, we concluded that the corrosion of reinforcing bars negatively influences the deformation corresponding to the ultimate load and energy dissipation capacity, which we expressed as the degradation factor. e effect of corrosion on reinforcing bars prior to the ultimate state and ultimate load was less significant. e energy dissipation of the flexural beams decreased with increasing half-cell potential. e energy dissipation of the specimen that exhibited the maximum absolute half-cell potential decreased by up to 30.1% compared to that of the control beam
Summary
Reinforced concrete (RC) structures are the most common structural systems in modern society, due to their low construction and maintenance costs and high durability compared to other types of structures. e structural performance of RC structures, deteriorates over time for various reasons, such as changes in the environmental conditions, design load, and material properties, as well as structural design errors and defective construction. E structural performance of RC structures, deteriorates over time for various reasons, such as changes in the environmental conditions, design load, and material properties, as well as structural design errors and defective construction Among these factors, reinforcement corrosion is one of the primary causes of deterioration, affecting a large number of RC structures [1,2,3,4,5,6,7,8,9,10]. (2) Brown patches in reinforced areas: when a steel bar starts to corrode, a layer of iron oxide is formed on top of the bar, which is carried to the surface of the concrete by moisture. The entire structure collapses due to the severe structural performance deterioration
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