Flexural-torsional buckling strength of I-girders with discrete torsional braces under various loading conditions: Fid-Bau Portal

Flexural-torsional buckling strength of I-girders with discrete torsional braces under various loading conditions

Nguyen, Canh Tuan / Joo, Hyun-Sung / Moon, Jiho / Lee, Hak-Eun

Highlights ► I-girders with discrete torsional bracings under various loadings were investigated. ► A solution for elastic flexuraltorsional buckling strength was presented. ► FEM analyses were conducted considering material nonlinearity, initial imperfection, and residual stresses. ► Inelastic flexural-torsional buckling strength was proposed and verified.

Abstract Torsional bracing systems have been used widely in I-girder bridges to increase the flexural-torsional buckling strength and distribute the load to the adjacent girders. To evaluate the required stiffness of the bracing and the flexural-torsional buckling strength of the I-girder with a multiple torsional bracing system, the equivalent continuous torsional bracing concept is often adopted regardless of the type of torsional bracing system. However, a previous study on the I-girder with discrete torsional bracings under uniform bending reported that the equivalent continuous torsional bracing concept has certain limitations on discrete torsional bracing problems and it needs to be investigated for general loading cases. This article presents an analytical solution for the elastic flexural-torsional buckling strength and stiffness requirements of I-girders with discrete torsional bracings under various loading conditions. First, a review was performed of the previous study on the elastic critical buckling moment and torsional stiffness requirement of the I-girder with discrete torsional bracings under uniform bending. This solution was then extended for various loading conditions. From the derived analytical solutions, the equivalent moment factor was proposed for practical engineering purposes and the proposed solutions were verified by comparing them with the results of finite element analysis and those of other previous studies. Finally, non-linear finite element analyses including the effects of the initial imperfection and residual stresses were conducted to examine the inelastic buckling strengths of I-girders with discrete torsional bracings under various loading conditions. The results showed that the buckling curves from the current design specification provide reasonably conservative flexural-torsional buckling strengths of the I-girder with discrete torsional bracings when the proposed elastic solutions are applied to obtain the buckling parameters.