Abstract
In fire scenarios, concrete-filled stainless steel tubular (CFSST) columns undergo initial loading at ambient temperature, loading during the heating phase as the fire develops, loading during the cooling phase as the fire dies out and continual loading after the fire. CFSST columns may fail some points during this process under combined fire and loading. In this paper, the failure modes and corresponding working mechanism of CFSST columns subjected to an entire loading and fire history are investigated. Sequentially coupled thermal-stress analyses in ABAQUS are employed to establish the temperature field and structural response of the CFSST column. To improve the precision of the finite element (FE) model, the influence of moisture on the thermal conductivity and specific heat of concrete during both the heating and cooling phases is considered using subroutines. Existing fire and post-fire test data of CFSST columns are used to validate the FE models. Comparisons between predicted and test results confirm that the accuracy of the FE models is acceptable; the FE models are then extended to simulate a typical CFSST column subjected to the entire loading and fire history. The behaviour of the CFSST column is explained by analysis of the temperature distribution, load versus axial deformation curves and failure response.
Highlights
Concrete-filled stainless steel tubular (CFSST) columns combine the advantages of concrete-filled steel tubular columns (CFST) and stainless steel, resulting in greater corrosion resistance, enhanced ductility and improved fire resistance [1,2,3]
Comparisons between predicted and test results confirm that the accuracy of the finite element (FE) models is acceptable; the FE models are extended to simulate a typical CFSST column subjected to entire loading and fire histories
To fill this research gap, this paper focuses on the influence of combined fire and loading on the response of CFSST columns by FE modelling
Summary
Concrete-filled stainless steel tubular (CFSST) columns combine the advantages of concrete-filled steel tubular columns (CFST) and stainless steel, resulting in greater corrosion resistance, enhanced ductility and improved fire resistance [1,2,3]. Some previous research has been conducted to investigate the combination of multi-phase fire and loading on CFST and steel reinforced concrete (SRC) structures. Yang et al [10] developed a fiber model to consider the influence of cooling on the post-fire performance of CFST columns. Song et al [11] developed an FE model to predict the load versus deformation relationships of CFST stub columns subjected to a combination of temperature and axial compression. Han et al [12] developed an FE model to study the postfire performance of SRC columns subjected to both loading and fire phases. To fill this research gap, this paper focuses on the influence of combined fire and loading on the response of CFSST columns by FE modelling. (3) Based on the validated FE models, the possible failure modes and corresponding response mechanism of a typical CFSST column during the entire loading and fire history are explained by analysis of temperature distribution, load versus axial deformation relations and load redistribution
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