Reinforcement corrosion is always a serious caused that lead to reducing strength and ductility of reinforcing bars, especially in bridges. This research examines the seismic performance of corroded wall piers (squat walls) and developed models for evaluating the seismic behavior of corroded squat walls. To observe the seismic behavior of corroded members, cyclic tests of large-scale wall specimens are conducted. The locations of
corrosion are examined only on the middle of the exterior of the walls which might be exposed directly to the corrosive causes. Accelerated corrosion using electrochemical method is used to impose corrosion to steel reinforcement. After the corrosion process, the wall will be tested using cyclic loading to examine the seismic performance. The wall after testing is demolished to investigate the corrosion condition of steel reinforcement.
Methods to estimate the residual shear strength of reinforced concrete squat walls with corroded reinforcement are proposed. Shear strength estimation based on average weight loss and minimum residual cross sectional area produces results that more reasonably described the experimental behavior. Empirical equations to estimate the residual beam flexural strength of corroded RC squat walls are proposed. A new evaluation method for shear strength and ultimate displacement was proposed in this research. Comparison with test results showed that the proposed method can capture the residual shear strength and ultimate displacement capacity of corroded squat walls
examined in this research.

Reinforcement corrosion is always a serious caused that lead to reducing strength and ductility of reinforcing bars, especially in bridges. This research examines the seismic performance of corroded wall piers (squat walls) and developed models for evaluating the seismic behavior of corroded squat walls. To observe the seismic behavior of corroded members, cyclic tests of large-scale wall specimens are conducted. The locations of
corrosion are examined only on the middle of the exterior of the walls which might be exposed directly to the corrosive causes. Accelerated corrosion using electrochemical method is used to impose corrosion to steel reinforcement. After the corrosion process, the wall will be tested using cyclic loading to examine the seismic performance. The wall after testing is demolished to investigate the corrosion condition of steel reinforcement.
Methods to estimate the residual shear strength of reinforced concrete squat walls with corroded reinforcement are proposed. Shear strength estimation based on average weight loss and minimum residual cross sectional area produces results that more reasonably described the experimental behavior. Empirical equations to estimate the residual beam flexural strength of corroded RC squat walls are proposed. A new evaluation method for shear strength and ultimate displacement was proposed in this research. Comparison with test results showed that the proposed method can capture the residual shear strength and ultimate displacement capacity of corroded squat walls
examined in this research.

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