Abstract
In this paper, the in-plane (IP) and out-of-plane (OP) interaction of masonry infill walls with various length-to-height ratios and vertical forces from dead and live loads are studied. For this purpose, calibrated numerical simulation for IP and OP behaviors of infilled frames has been exploited. In this method, first, the vertical loads are applied, then increasing IP displacement is imposed at the top of the models and finally OP demands are applied to the walls up to their failure. Two different methods of applying OP loading are studied: increasing static uniform pressure on the wall, and increasing dynamic acceleration. Three levels of IP displacement demands are considered: at the first reduction of tangential stiffness for IP force-displacement response, at the maximum IP strength, and at the displacement related to 20 % reduction of IP strength. The results obviously show that up to the point of the maximum IP strength capacity, the OP behavior of the considered models slightly enhanced due to the effects of improved arching actions originated from the development of IP compressive diagonal struts. Moreover, slight differences exist between the static and dynamic loadings in OP direction, hence proving the accuracy of the equivalent static loading in determining OP capacity for the studied infilled frames. Comparing the results of masonry infilled frames with those of the corresponding masonry walls indicate that the IP displacements negatively affect the OP strength in the latter, even at small IP displacement demands; however, the rate of OP strength reduction in larger IP drift ratios is lower compared to that of the corresponding infilled frame.
Highlights
One of the most drastic challenges in the evaluation of many existing frame buildings is the understanding of real seismic performance of their infill wall elements
The results of this study clearly indicate that up the point of IP ultimate strength (SME) for infilled frames, regardless of their aspect ratio and existence of vertical loads on the top beam and the columns, the OP strength capacity is insensitive to the IP displacement demands
Unlike the unreinforced masonry walls in which they experience considerable reduction in the OP strength capacity even by applying a small IP displacement [24, 25], masonry infill walls benefit from the positive effects of formation of IP diagonal compressive struts in improving the arching action as well as in increasing their OP strength capacity
Summary
One of the most drastic challenges in the evaluation of many existing frame buildings is the understanding of real seismic performance of their infill wall elements. Angel and Abrams [3] stated that the OP capacity of masonry infilled reinforced concrete frames can reduce to half as a result of in-plane displacements and such dependency is more visible in high slenderness ratios. Kuang and Yuen [4] concluded that OP loadings on masonry infilled reinforced concrete frames can reduce their in-plane (IP) capacity up to 30 %. This result opposes with Alinejad’s [5] which shows an insignificant IP capacity reduction of the OP damages; while stating that the opposite is more important. The results in terms of OP strength reduction due to IP demands are elaborated and compared with those of the corresponding studies in terms of IP-OP interaction curves
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