A. A. Tasnimi, M. A. Rezazadeh,
Volume 10, Issue 3 (September 2012)
The torsional capacity of unreinforced masonry brick buildings is generally inadequate to provide a stable seismic behavior. The
torsional strength is believed to be the most important parameter in earthquake resistance of masonry buildings and the shear
stresses induced in the bed joints of such building’s walls is an important key for design purposes. Brick buildings strengthened
with wire-mesh reinforced concrete overlay are used extensively for building rehabilitation in Iran. Their quick and simple
applications as well as good appearance are the main reasons for the widespread use of such strengthening technique. However,
little attention has been paid to torsional strengthening in terms of both experimental and numerical approach. This paper reports
the response and behavior of two single-story brick masonry buildings having a rigid two-way RC floor diaphragm. Both
specimens were tested under monotonic torsional moment.Numerical work was carried out using non-linear finite element
modeling. Good agreement in terms of torque–twist behavior, and crack patterns was achieved. The unique failure modes of the
specimens were modeled correctly as well. The results demonstrate the effectiveness of reinforced concrete overlay in enhancing
the torsional response of strengthened building. Having evaluated the verification of modeling, an unreinforced brick building
with wall-to-wall vulnerable connections was modeled so that the effect of these connections on torsional performance of brick
building could be studied. Then this building was strengthened with reinforced concrete overlay and the effect of strengthening
on torsional performance of brick buildings with vulnerable connections was predicted numerically.