Abstract

The axial compressive experiments were carried out on 21 welded composite T-shaped concrete-filled steel tubular columns, and 395 finite element models were established for parameter calculation. The calculating formula of axial compressive bearing capacity of welded composite T-shaped concrete-filled steel tubular columns is established. The results show that three typical failure modes were found: middle buckling, end local buckling, and integral bending. When the slenderness ratio λ exceeds the elastic instability limit λp, the axial stress of steel is lower than yield strength fy, and the axial stress of core concrete is lower than axial compressive strength fc. Increasing the thickness of steel has a more obvious effect on increasing the axial compressive bearing capacity of specimen. The theoretical calculating formula can effectively predict the axial compressive bearing capacity, and the theoretical calculation is partial to safety. The average ratio of axial compressive bearing capacity of the theoretical calculation to the experimental is 0.909, and the standard deviation is 0.075. The average ratio of axial compressive bearing capacity of the finite element calculation to the experimental is 0.957, and the standard deviation is 0.045. The average ratio of axial compressive bearing capacity of the theoretical calculation to the finite element calculation is 0.951, and the standard deviation is 0.039.

Highlights

  • In high-rise buildings, the application of concrete-filled steel tubular (CFST) columns can effectively solve the ratio of the axial loading to the cross-sectional area of bottom columns, and give full play to the advantages of high bearing capacity of CFST columns

  • Yang et al.[9] carried out axial compressive experiment on T-shaped CFST short columns with stiffeners, analyzed the influence of stiffener setting on its mechanical performance, and put forward the calculating formula of axial compression bearing capacity

  • Through regression analysis of the experiment and finite element calculation, the calculating formula of relationship between stability coefficient u and slenderness ratio l is shown in equation (13)

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Summary

Introduction

In high-rise buildings, the application of concrete-filled steel tubular (CFST) columns can effectively solve the ratio of the axial loading to the cross-sectional area of bottom columns, and give full play to the advantages of high bearing capacity of CFST columns.

Effective lateral constraining stress fi
Average effective lateral constraining stress f10
Findings
Conclusion

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