Abstract
Orthotropic Steel Decks have been used in long-span bridges for several decades because of their high capacity to weight ratio. However, many fatigue related issues have been reported. This paper provides an overview of the main existing fatigue prediction models and discusses their relevance for the fatigue life assessment of Orthotropic Steel Bridge Decks (OSBDs). Several case studies have proven the importance of considering the combined effect of wind and traffic loadings to estimate the fatigue life of long-span bridges. The importance of incorporating welding residual stresses is also well documented while it is often disregarded in design practices. Reliability-based fatigue assessment methods make it possible to quantify how the sources of uncertainty related to loading conditions, welding residual stresses or fabrication defects can affect the fatigue reliability of OSBDs. Monte Carlo simulations are often used to perform probabilistic analyses, but machine-learning algorithms are very promising and computationally efficient. The shortcomings of the Palmgren-Miner rule are discussed and the need for alternative damage accumulation indexes is clear. A number of conclusions are drawn from the analysis of fatigue tests conducted on OSBDs.
Highlights
Orthotropic Steel Bridge Decks (OSBDs) appeared in the 1920s
Agerskov [37] showed, through fatigue tests and fracture mechanics analyses, that the use of the Palmgren-Miner rule (PM rule) could lead to unconservative results as it fails to capture the effect of crack closure mechanisms by overlooking the distribution between tensile and compressive stresses and the presence of welding residual stresses
Summary and future research Summary of the relevant key findings and reflections regarding future work within the fatigue life assessment methods for welded joints in orthotropic steel decks of long-span bridges is presented
Summary
Orthotropic Steel Bridge Decks (OSBDs) appeared in the 1920s They are characterized by a low dead weight and a high loading bearing capacity. Two main locations emerge as the most likely locations for fatigue cracks in traditional OSBDs: Rib-decks joints (19% of cases) and Rib-diaphragm. As mentioned by Leendertz [5], many small fatigue cracks in rib-diaphragm joints with and without cope holes were revealed by routine inspections. In his doctoral thesis, Kolstein [6] studied two additional welded joints in a typical OSBD: Butt joint in the deck plate Diaphragm to deck plate joint.
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