A novel column consisting of steel, concrete and fiber-reinforced polymer (FRP) is presented and assessed
through experimental study. The sectional form of steel–concrete–FRP–concrete (SCFC) columns has a
square steel tube as the outer layer and a circular filament-wound FRP tube as the inner layer, and concrete
is filled between these two layers and within the FRP tube. Thus the column can be regarded as a
concrete-filled square steel tube (CFST) with a FRP-confined concrete core (FCCC). In comparison to existing
composite column sections, several advantages are achieved such as ease of connection to beams, the
stronger confinement of core concrete, ductile response, and residual load capacity. 18 SCFC stub columns
are tested with different concrete strengths, FRP tube thickness and steel tube thickness in comparison to
four traditional composite columns. The distinctive behaviors of SCFC columns, including significant
post-yield stiffness, ductile failure, and stable residual bearing capacity are found. Test results show that
the strengths of concrete, FRP, and steel are effectively utilized at different stages, including the initial
linear stage, the secondary linear stage (hardening stage), and the post-peak stage. The influences of
key design parameters on the mechanical characteristics of initial compressive stiffness, peak strain,
residual load-bearing capacity, and ductility are also clarified
A novel column consisting of steel, concrete and fiber-reinforced polymer (FRP) is presented and assessedthrough experimental study. The sectional form of steel–concrete–FRP–concrete (SCFC) columns has asquare steel tube as the outer layer and a circular filament-wound FRP tube as the inner layer, and concreteis filled between these two layers and within the FRP tube. Thus the column can be regarded as aconcrete-filled square steel tube (CFST) with a FRP-confined concrete core (FCCC). In comparison to existingcomposite column sections, several advantages are achieved such as ease of connection to beams, thestronger confinement of core concrete, ductile response, and residual load capacity. 18 SCFC stub columnsare tested with different concrete strengths, FRP tube thickness and steel tube thickness in comparison tofour traditional composite columns. The distinctive behaviors of SCFC columns, including significantpost-yield stiffness, ductile failure, and stable residual bearing capacity are found. Test results show thatthe strengths of concrete, FRP, and steel are effectively utilized at different stages, including the initiallinear stage, the secondary linear stage (hardening stage), and the post-peak stage. The influences ofkey design parameters on the mechanical characteristics of initial compressive stiffness, peak strain,residual load-bearing capacity, and ductility are also clarified
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