Abstract
Non-structural masonry partition walls, which are mainly designed to functionally separate spaces in the buildings and provide physical barriers between rooms, were traditionally built from either solid or hollow clay units or autoclaved aerated concrete blocks. Recent earthquakes have revealed the high vulnerability of these elements, even in the case of low to moderate seismic events. Public buildings (e.g., hospitals and schools) are particularly vulnerable. Due to their greater floor-to-floor heights and the response spectra of floors, the dynamic response of primary structure may provoke significantly higher seismic loads on partition walls. The main goal of the presented experimental study was to investigate the behavior of slender partition walls loaded out-of-plane with a simple and cost-effective approach that may be applied through routine refurbishment works. Eleven full-scale slender non-structural masonry partition walls were built with brickwork and cement–lime mortar. Eight of them were additionally strengthened with different techniques, including glass fiber-reinforcing fabric and low-cost glass fiber-rendering mesh. To evaluate the efficiency of the applied strengthening solutions, out-of-plane quasi-static cyclic experiments were conducted. By applying meshes over the entire surfaces, the resistance was significantly improved with the low-cost approach reaching half of the resistance of the commercially available strengthening system preserving the same displacement capacity.
Highlights
Seismic activity has been a driver of widespread damage and destruction in numerous locations around the globe
This study investigated new strengthening techniques to prevent the out-of-plane collapse of non-structural masonry partition walls in future earthquakes by using flexible adhesives and glass fiber reinforcement
Quasistatic cyclic tests were performed on eleven full-scale non-structural wall specimens
Summary
Seismic activity has been a driver of widespread damage and destruction in numerous locations around the globe. Various composite materials are used, such as carbon fiber-reinforced polymers (CFRP) [25,26,27,28], glass fiber-reinforced polymers (GFRP) [29,30,31,32], basalt fiber-reinforced polymers (BFRP) [26,33], and others They are externally attached (e.g., [34]) or near surface mounted (e.g., [35]) to existing walls in various ways, commonly using epoxy resins. The only out-of-plane experimental research on non-structural masonry walls’ strengthening was performed by Stempniewski et al [57]; glass fiber composite fabric was applied to existing non-structural masonry walls with flexible polyurethane adhesive. The strengthening of built walls was applied with four different systems using glass fiber mesh
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