Abstract
This paper evaluates the effects of horizontal web reinforcement on cyclic behaviour of RC squat wall using test results of three pairs of specimens. One specimen was tested by the authors while the other five were adopted from the existing researches. Each specimen pair was designed with approximately the same design parameters, except that uniformly distributed horizontal web reinforcement was provided in one specimen only. Shear stress demand, evaluated based on the shear associated with the development of flexural strength at the base, was approximately $3.5\sqrt {{{f'}_c}} (psi)$, $6.0\sqrt {{{f'}_c}} (psi)$, and $8.0\sqrt {{{f'}_c}} (psi)$, respectively, for each specimen pair. Test results show that specimen with uniformly distributed horizontal web reinforcement exhibited larger deformation capacity compared to specimens without it. Specimen peak strengths, on the other hand, appear to be similar with and without uniformly distributed horizontal reinforcement and can be satisfactorily predicted by nominal flexural strength.
Highlights
Reinforced concrete (RC) shear wall provides lateral strength and keeps lateral deformation within acceptable limits due to its large in-plane stiffness
Under approximately 0.08Agfc’ axial force and monotonically increased lateral displacement, test results showed that two specimens exhibited similar peak lateral strength but slightly different deformation capacity
This study aims to extend the experimental work of the aforementioned researches and systematically investigate the effects of uniformly distributed horizontal web reinforcement on cyclic behavior of RC squat wall with high shear stress demand
Summary
Reinforced concrete (RC) shear wall provides lateral strength and keeps lateral deformation within acceptable limits due to its large in-plane stiffness. Researches on effects of horizontal reinforcement on load-deformation responses of RC squat walls have been conducted previously [2, 3]. Maier [2] tested a total of 10 squat wall specimens with hw⁄lw of around 1.10. Under approximately 0.08Agfc’ axial force and monotonically increased lateral displacement, test results showed that two specimens exhibited similar peak lateral strength but slightly different deformation capacity. Similar findings were reported by Greifenhagen and Lestuzzi [3] from results of specimens M1 and M2 with hw⁄lw of around 0.70 as well.
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