Abstract EN:

Torsional behaviour of steel beams is deeply influenced by the shape of the cross section. Thin-walled open profiles, are very common in steel constructions. The classical theory of beams of Saint Venant under-estimates the strength of such profiles. In order to obtain more realistic results, it is necessary to adopt the so-called non-uniform torsion theory of Vlassov. In the first theory, a twisting of such a shaft produce only pure shear stresses. When analysing the torsional behaviour of thin walled beams according to the second theory, we remark that in addition to the shear stresses, the additional normal stresses arising from warping are developed in the cross section. If the beam is loaded in the plane of this weak axis and is not adequately braced lateraly, the beam will bend out of plane and twist when the load has reached a critical value. This phenomenon is known as lateral buckling. The analytical and numerical methods are used to determine the critical load for beams with monosymmetric cross-sections, subjected to transversal loads and moment gradients. The analytical method is obtained from the solution of the differential equations. A general formula to obtain the elastic lateral buckling solution is presented. In the numerical method, we use the Raleigh-Ritz energy approach. Results are presented in terms of the degree of section monosymmetry, slender of the beam and load height parameter. Our results are compared with ABAQUS code and with Eurocode 3 results. The performance of these results are very satifsfactory.