Title:
Flexural and Shear Response of Reinforced Masonry Walls
Author(s):
P. B. Shing, M. Schuller, V. S. Houskere, and E. Carter
Publication:
Structural Journal
Volume:
87
Issue:
6
Appears on pages(s):
646-656
Keywords:
clays; concrete blocks; cyclic loads; ductility; energy; walls; earthquake-resistant structures; evaluation; flexural strength; shearwalls; lateral pressure; masonry; reinforced masonry; reinforcing steels; shear strength; Structural Research
DOI:
10.14359/2957
Date:
11/1/1990
Abstract:
The flexural and shear behavior of reinforced masonry shearwalls subject to both monotonic and cyclic lateral loads is examined. The study is based on the experimental results obtained from more than twenty 6 x 6 ft (1.83 x 1.83 m) reinforced masonry wall panels tested under in-plane vertical and lateral loads. The flexural strength and deformation capability of a squat wall can be accurately evaluated by means of the simple flexure theory based on the plane-section assumption. Moreover, the shear strength dominated by diagonal cracking can be attributed to several complicated mechanisms. For the square wall panels studied, the shear strength is initially provided by the diagonal compression strut mechanism, and later by the interface shear, as well as the resistance of the horizontal reinforcement. A simple shear formula, based on the latter and proposed in a prior study, appears to be reliable. In general, wall panels that failed in shear exhibited a more brittle behavior than those that failed in flexure. Furthermore, based on experimental data, an empirical formula governing the degradation of shear strength under cyclic displacement reversals is developed.