Abstract
It is rather costly and difficult to experimentally evaluate the performance of concrete-filled tubular (CFT) circular steel columns exposed to combined axial and cyclic lateral loads. This research paper uses the nonlinear finite element (NLFEA) technique to assess the influence of using carbon-fiber-reinforced polymer (CFRP) laminates on the structural response and failure mode of damaged-by-sulfate CFT circular steel columns. At the beginning, twenty-one CFT circular steel column models were devised and checked for soundness using the findings of previously conducted research. Next, the models were broadened to investigate how the models’ behavior was influenced by the CFRP number of layers and the level of sulfate damage. For experimental purposes, the numbers of CFRP layers were set to be zero, five, six, seven, eight, nine, and ten, while there were three levels of sulfate damage, namely: level 0 (undamaged), level 1 (73 days), and level 2 (123 days). Some of the models were left unconfined with CFRP wraps for comparison. The CFRP confinement was at the end of the models due to its importance regarding the models’ capacity of lateral load. The columns’ ends were confined to prevent the models from outward local buckling, which led to higher strength, bigger net drift, and enhanced energy dissipation. The NLFEA models were then appropriately modified and adjusted in accordance with credible previously conducted experimental research; after which, a parametric study was performed to investigate how the models’ behavior was affected by the number of CFRP layers and the level of axial load. The study found that the CFT circular steel column models’ performance significantly enhanced when the models were wrapped with five to ten CFRP layers. It must be mentioned, though, that using eight, nine, and ten CFRP layers gave almost similar results. In addition, the NLFEA results revealed that when the damaged-by-sulfate models were repaired externally with CFRP wraps, there was an improvement in the models’ cyclic behavior, as they showed a raise in the load capacity, an enhancement in the horizontal displacement, a greater displacement ductility, better energy dissipation, and little deterioration in secant stiffness. The study found that using wraps of CFRP proved a great efficiency with the change in the sulfate damage level.
Highlights
Outward local buckling has always been a big problem when dealing with concretefilled tubular (CFT) steel columns, as the inward portion is stopped by the concrete poured inside
Xiao [4] suggested a method to confine the ends of CFT columns with wraps of FRP to avoid the occurrence of outward local buckling, enhance the columns’ ductility and strength, and improve the effectiveness of the inner concrete, at the columns’ ends with high stresses [4–6]
C indicates carbon-fiber-reinforced polymer (CFRP) and X is the number of CFRP layers; and S x, where S indicates sulfate and x represents the level of attack
Summary
Outward local buckling has always been a big problem when dealing with concretefilled tubular (CFT) steel columns, as the inward portion is stopped by the concrete poured inside. Whether in sway or moment resisting frames, the CFT columns are exposed to axial loads and to lateral winds/seismic loadings, which generate moments in columns, at the ends. Xiao [4] suggested a method to confine the ends of CFT columns with wraps of FRP to avoid the occurrence of outward local buckling, enhance the columns’ ductility and strength, and improve the effectiveness of the inner concrete, at the columns’ ends with high stresses [4–6]. Confining CFT steel columns with wraps of FRP was investigated for effectiveness by a number of studies [7–16]. The wrapped-with-FRP CFT circular glass columns were experimented upon when they were exposed to monotonic [6] and cyclic [17,18]
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