Abstract
To research the web crippling performance (i.e., the ultimate web crippling bearing capacity and ductility) of high-strength cold-formed (HSCF) rectangular steel tubes under concentrated load, thirty-six specimens with different bearing plate width, width-to-height ratio, boundaries, and loading conditions are fabricated and tested in this paper. Particularly, four kinds of boundaries and loading conditions are utilized, including end-two-flange (ETF), end-one-flange (EOF), interior-two-flange (ITF), and interior-one-flange (IOF). Research revealed the failure modes of HSCF rectangular steel tubes under concentrated loads applied at the end or interior. Moreover, the load-displacement curves and load-strain curves are obtained. The results show that the ultimate crippling capacity of webs increases significantly with larger bearing plate width and width-to-height ratio. Specimens subjected to interior bearing load have higher ultimate strength and deformation capacity than counterparts that are subjected to bearing load at the end. Additionally, in the middle of the compression web, all strain measuring points enter the plasticity stage and finally appear in the plastic hinge area. Subsequently, the failure modes and ultimate bearing capacity are simulated by the finite element method (FEM), which is implemented via ABAQUS. By comparing the test results with the numerical values, demonstrate the effectiveness of the proposed numerical simulation on investigating the failure modes and the ultimate bearing capacity of HSCF rectangular steel tubes. Finally, regarding the conservative and dangerous calculation of web crippling ultimate bearing capacity in current codes, we can provide a good guidance for future work, particularly the proposed calculation equations for ultimate bearing capacity of HSCF rectangular steel tubes.
Highlights
To research the web crippling performance of high-strength coldformed (HSCF) rectangular steel tubes under concentrated load, thirty-six specimens with different bearing plate width, width-toheight ratio, boundaries, and loading conditions are fabricated and tested in this paper
According to the existing design rules [19,20,21], there are four stipulated loading conditions, including end-one-flange (EOF), interior-one-flange (IOF), end-two-flange (ETF), and interior-two-flange (ITF), which are classified via the position of the centralized loading on one or both flanges. e influence of cold-formed steel sections with web openings on the web crippling performance was studied by Uzzaman et al [22, 23], and the results showed that the first three factors affecting the web crippling strength were hole depth, bearing plate length, and web flat depth
The web crippling of high strength cold-formed (HSCF) steel tubes under other loading conditions has been studied [34, 35], and it is found that the existing codes are not very practical since there is an obvious difference between measured strength and the nominal strength stipulated via codes. us, based on the experimental and numerical results, they evaluated and improved the existing codes about web crippling
Summary
To research the web crippling performance (i.e., the ultimate web crippling bearing capacity and ductility) of high-strength coldformed (HSCF) rectangular steel tubes under concentrated load, thirty-six specimens with different bearing plate width, width-toheight ratio, boundaries, and loading conditions are fabricated and tested in this paper. By comparing the test results with the numerical values, demonstrate the effectiveness of the proposed numerical simulation on investigating the failure modes and the ultimate bearing capacity of HSCF rectangular steel tubes. Li and Young [33] conducted the web crippling tests of HSCF steel rectangular hollow sections under load conditions at the end and interior, and they verified the effectiveness of the proposed finite element model (FEM) by comparing the experimental results with the numerical values. The web crippling performance of HSCF rectangular steel tubes under concentrated load was studied
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