Performance Evaluation of FRP Bridge Deck Under Shear Loads

Prachasaree, Woraphot; GangaRao, Hota V. S.; Shekar, Vimala

doi:10.1177/0021998308099753

Cited by 8 publications

(1 citation statement)

References 12 publications

(9 reference statements)

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“…6,15, [16][17][18][19][20][21][22] Strength and deformation prediction: Theoretical development of strength and deformation prediction and experimental validation (coupons and full-scale specimens). 6,15,19,[23][24][25][26][27] Stability evaluation: Theoretical development and experimental evaluation of local and global buckling, as well as warping under torsion. 6,14,20,23 Limit states: To define the limit states of deflection and rotation (deformations) for various spans of pultruded sections used in design.…”

Section: Introductionmentioning

confidence: 99%

Response of closed Glass Fiber Reinforced Polymer sections under combined bending and torsion

Qureshi

GangaRao

Hayat

et al. 2016

Journal of Composite Materials

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Structural response under combined bending (M) and torsion (T) of pultruded Glass Fiber Reinforced Polymer composite hollow circular and square sections has been investigated, using unique experimental facility for combined loads. Prior to determining combined response, bending and torsional strengths at failure were found separately for all test sections. To evaluate structural response, strain gages were attached at 6 to 12 critical locations of each specimen. For each cross-section, three samples were tested under combined load combinations, i.e. (0.25 M max , T Failure ), (0.50 M max , T Failure ) and (0.75 M max , T Failure ). The results have been presented as M vs ", T vs , and M=M max vs T=T max . Local bending effect are found to be significant under point loads, even though they are distributed over a small area. The interactive plots exhibited three distinct zones, i.e. bending moment dominated zone, torque dominated zone, and transition zone. The failure modes revealed a distinct pattern with crack initiation sites and propagation directions. The potential energy method of bent and twisted specimens of isotropic thin-walled sections has been extended to thin-walled orthotropic members. Finite element analyses using ANSYS-SHELL181 was carried out to develop torsion-bending interaction response and compare with experimental data. Principal strain to failure predictions under combined loads, except under pure bending, resulted in a constant strain to failure for a given fiber architecture.

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