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A platform for research: civil engineering, architecture and urbanism
Flexural behavior of lean duplex stainless steel girders with slender unstiffened webs
Abstract The behavior of lean duplex stainless steel plate girders (LDIPGs) with slender unstiffened webs is studied in this paper. Firstly, shell finite element models are validated using experimental test results available in the literature. Secondly, these models are used to investigate the behavior of LDIPGs subjected to uniform bending. Parametric studies for the LDIPGs are carefully designed based on three parameters: the radius of gyration of the compression flange (rT), the section modulus (Sx), and the unbraced length (Lb). The results showed that LDIPGs with higher rT but similar Sx values can attain higher flexural strengths compared to their yield strengths because of the higher torsional rigidity of the flanges and stockier webs. On the other hand, by increasing the Sx value of the girder but keeping fixed the rT values, the moment carried by the girder is found relatively to decrease with the simultaneous increase in the amount of steel. Finally, the numerical results are compared with predictions given by design standards. It is found that the EC3 provides conservative bending predictions. Accordingly, the imperfection factor associated to buckling curve (c) is recommended to be used in the scope of the design method provided by EN 1993-1-4.
Highlights A finite element model for the LDIPGs under uniform bending is presented. The verified finite element model is used to study the behavior of LDIPGs. The LDIPGs are designed based on the radius of gyration and the section modulus. The proposed design method is shown to predict well the strengths of LDIPGs.
Flexural behavior of lean duplex stainless steel girders with slender unstiffened webs
Abstract The behavior of lean duplex stainless steel plate girders (LDIPGs) with slender unstiffened webs is studied in this paper. Firstly, shell finite element models are validated using experimental test results available in the literature. Secondly, these models are used to investigate the behavior of LDIPGs subjected to uniform bending. Parametric studies for the LDIPGs are carefully designed based on three parameters: the radius of gyration of the compression flange (rT), the section modulus (Sx), and the unbraced length (Lb). The results showed that LDIPGs with higher rT but similar Sx values can attain higher flexural strengths compared to their yield strengths because of the higher torsional rigidity of the flanges and stockier webs. On the other hand, by increasing the Sx value of the girder but keeping fixed the rT values, the moment carried by the girder is found relatively to decrease with the simultaneous increase in the amount of steel. Finally, the numerical results are compared with predictions given by design standards. It is found that the EC3 provides conservative bending predictions. Accordingly, the imperfection factor associated to buckling curve (c) is recommended to be used in the scope of the design method provided by EN 1993-1-4.
Highlights A finite element model for the LDIPGs under uniform bending is presented. The verified finite element model is used to study the behavior of LDIPGs. The LDIPGs are designed based on the radius of gyration and the section modulus. The proposed design method is shown to predict well the strengths of LDIPGs.
Flexural behavior of lean duplex stainless steel girders with slender unstiffened webs
Hassanein, M.F. (author) / Silvestre, N. (author)
Journal of Constructional Steel Research ; 85 ; 12-23
2013-02-21
12 pages
Article (Journal)
Electronic Resource
English
Flexural behavior of lean duplex stainless steel girders with slender unstiffened webs
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