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Behavior of beam web panel under opposite patch loading
Abstract Elastic buckling is studied for a panel with various boundary conditions including simple supports, fixed supports and elastic restraints. The panel is subjected to opposite patch loading. Following a review of existing work on the effects of localized compression, also known as patch loading, a study is conducted to take into account the restraints provided by the flanges of the I beam in a realistic manner. This study is based on a finite element model implemented in the CAST3M software. A new equation is proposed to calculate the buckling critical coefficient for a beam web panel considering the rotational stiffness provided by the flanges. The model is then applied to longitudinally stiffened web panels which are subjected to opposite patch loading. A parametric analysis is performed to determine the transition from a global buckling mode to a local buckling mode where the sub-panels on each side of the stiffener behave separately. The numerical results show that the flexural rigidity of the stiffener is the appropriate parameter that governs the buckling mode. From these results, a formula is proposed to calculate the buckling critical coefficient of stiffened web panels.
Highlights ► Elastic buckling is studied for I beam web panels subject to opposite patch loading. ► Equation is proposed to calculate the buckling critical coefficient for I beam. ► The data used in deriving the equation are generated by a finite element model. ► Formula is proposed to calculate the buckling coefficient of stiffened web panels.
Behavior of beam web panel under opposite patch loading
Abstract Elastic buckling is studied for a panel with various boundary conditions including simple supports, fixed supports and elastic restraints. The panel is subjected to opposite patch loading. Following a review of existing work on the effects of localized compression, also known as patch loading, a study is conducted to take into account the restraints provided by the flanges of the I beam in a realistic manner. This study is based on a finite element model implemented in the CAST3M software. A new equation is proposed to calculate the buckling critical coefficient for a beam web panel considering the rotational stiffness provided by the flanges. The model is then applied to longitudinally stiffened web panels which are subjected to opposite patch loading. A parametric analysis is performed to determine the transition from a global buckling mode to a local buckling mode where the sub-panels on each side of the stiffener behave separately. The numerical results show that the flexural rigidity of the stiffener is the appropriate parameter that governs the buckling mode. From these results, a formula is proposed to calculate the buckling critical coefficient of stiffened web panels.
Highlights ► Elastic buckling is studied for I beam web panels subject to opposite patch loading. ► Equation is proposed to calculate the buckling critical coefficient for I beam. ► The data used in deriving the equation are generated by a finite element model. ► Formula is proposed to calculate the buckling coefficient of stiffened web panels.
Behavior of beam web panel under opposite patch loading
Mezghanni, O. (author) / Averseng, J. (author) / Bouchaïr, A. (author) / Smaoui, H. (author)
Journal of Constructional Steel Research ; 83 ; 51-61
2012-12-28
11 pages
Article (Journal)
Electronic Resource
English
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