Bridge deck analysis of transversely post-tensioned concrete box girder bridges

J. Edmunds; L. Franco; Thushara Jayasinghe; Thusitha Ginigaddara; Paulo Vaz-Serra; Priyan Mendis

doi:10.56748/ejse.234101

Authors

J. Edmunds University of Melbourne
L. Franco University of Melbourne
Thushara Jayasinghe University of Melbourne https://orcid.org/0000-0003-1139-9072
Thusitha Ginigaddara University of Melbourne https://orcid.org/0000-0002-6951-2384
P Vaz-Serra University of Melbourne
Priyan Mendis University of Melbourne

DOI:

https://doi.org/10.56748/ejse.234101

Keywords:

bridge deck, grillage analysis, transversely post-tensioned concrete box girders

Abstract

For rural bridges in Australia, a common design practice is pouring in-situ concrete on top of beams in order to tie all the beams together and distribute load. However, pouring concrete on-site creates more risk and contractors prefer to avoid it. Another method is using transverse post tensioning to tie beams. This article investigated the behaviour of transverse post-tensioning bars in providing load distribution between beams and ultimately comment on their effectiveness compared to in-situ poured decks. Currently, the industry has not completely investigated this matter in order to design post-tensioning accurately. Conservative estimates are currently used in industry today. Current practice is 50% of the design load on the beam where the load is applied in their design assumptions which is quite high. The team modelled concrete box girder bridges with transverse post-tensioning using grillage method. Several factors were investigated including bridge length and width, bridge skew and beam type. From the models, the team concluded that increasing the bridge span increases the load distribution, the load distribution difference is negligible for skew between 0 and 20 degrees and larger shear actions are observed with increased skew and width. It was determined that the worst-case total load on the beam where the load as applied was found to be 40.5%, 9.5% less than current practice. It is recommended that a similar investigation is conducted using a finite element method to gain a deeper understanding.

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