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Axial-moment interaction of high strength concrete encased steel composite columns: Experimental investigation
Abstract This paper investigates the failure mechanism and structural behavior of high strength Concrete Encased Steel (CES) composite columns subject to compression and bending. Twelve composite column specimens with C90 concrete and S500 steel section were tested under concentric compression, eccentric compression and four-point bending. All specimens had the same geometry and were reinforced with the same steel section and same amount of reinforcing bars. In some specimens, micro steel fiber was added into concrete mix with 0.5% or 1.0% dosage to delay or prevent the potential premature cover spalling. The load-carrying capacity, load-deformation response, post-peak ductility, flexural stiffness, as well as damage pattern are comprehensively analyzed. Comparison is made between the experimental results and analytical predictions using modern design codes such as EN 1994-1-1 and AISC 360–16. From the four-point bending test, the flexural stiffness obtained from the test seems to be smaller than the codes' predicted values, indicating that modification is needed to achieve better prediction of structural response of composite beams at the service load level. As for the axial force (N)-bending moment (M) strength interaction diagram, it is found AISC 360–16 gives overall more conservative prediction than EN 1994-1-1 method for high strength CES columns with C90 concrete and S500 steel. However, both methods overestimate the axial compression capacity although they can predict their flexural capacity well.
Graphical abstract Display Omitted
Highlights Twelve concrete encased steel (CES) composite columns made of high strength steel and concrete were tested to failure. The strength and ductility of high strength CES composite columns were determined. The effective flexural stiffness of beam specimens was analyzed. The axial-moment interaction strength curves from tests were compared with those predicted by the design codes.
Axial-moment interaction of high strength concrete encased steel composite columns: Experimental investigation
Abstract This paper investigates the failure mechanism and structural behavior of high strength Concrete Encased Steel (CES) composite columns subject to compression and bending. Twelve composite column specimens with C90 concrete and S500 steel section were tested under concentric compression, eccentric compression and four-point bending. All specimens had the same geometry and were reinforced with the same steel section and same amount of reinforcing bars. In some specimens, micro steel fiber was added into concrete mix with 0.5% or 1.0% dosage to delay or prevent the potential premature cover spalling. The load-carrying capacity, load-deformation response, post-peak ductility, flexural stiffness, as well as damage pattern are comprehensively analyzed. Comparison is made between the experimental results and analytical predictions using modern design codes such as EN 1994-1-1 and AISC 360–16. From the four-point bending test, the flexural stiffness obtained from the test seems to be smaller than the codes' predicted values, indicating that modification is needed to achieve better prediction of structural response of composite beams at the service load level. As for the axial force (N)-bending moment (M) strength interaction diagram, it is found AISC 360–16 gives overall more conservative prediction than EN 1994-1-1 method for high strength CES columns with C90 concrete and S500 steel. However, both methods overestimate the axial compression capacity although they can predict their flexural capacity well.
Graphical abstract Display Omitted
Highlights Twelve concrete encased steel (CES) composite columns made of high strength steel and concrete were tested to failure. The strength and ductility of high strength CES composite columns were determined. The effective flexural stiffness of beam specimens was analyzed. The axial-moment interaction strength curves from tests were compared with those predicted by the design codes.
Axial-moment interaction of high strength concrete encased steel composite columns: Experimental investigation
Lai, Binglin (author) / Liew, J.Y. Richard (author)
2020-09-20
Article (Journal)
Electronic Resource
English