Coupled Flexural-Lateral-Torsional of Shear Deformable Thin-Walled Beams with Asymmetric Cross-Section – Closed Form Exact Solution

Year 2015, Volume: 1 Issue: 7 - SPECIAL ISSUE 2 Energy Systems and Developments 2015 ICESD 2015 INDIA, 659 - 669, 01.07.2015

Mohammed Hjaji

https://doi.org/10.18186/jte.75509

Cited By: 1

Abstract

This paper develops the exact solutions for coupled flexurallateral-torsional static response of thin-walled asymmetric open members subjected to general loading. Using the principle of stationary total potential energy, the governing differential equations of equilibrium are formulated as well as the associated boundary conditions. The formulation is based on a generalized TimoshenkoVlasov beam theory and accounts for the effects of shear deformation due to bending and warping, and captures the effects of flexural– torsional coupling due to cross-section asymmetry. Closed-form solutions are developed for cantilever and simply supported beams under various forces. In order to demonstrate the validity and the accuracy of this solution, numerical examples are presented and compared with well-established ABAQUS finite element solutions and other numerical results available in the literature. In addition, the results are compared against non-shear deformable beam theories in order to demonstrate the shear deformation effects.

Keywords

Asymmetric cross-section, Flexural-Lateral-torsional response, Vlasov-Timoshenko beam theory, closed-form solution

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