Abstract
Bridges are critical for transportation networks. Temporary closures due to poor maintenance may trigger adverse cascading events, affecting economic and societal well-being. Two main factors play a key role in bridge health conditions: ageing and wear-and-tear due to the increasing traffic. This paper proposes a comprehensive framework to quantify the combined phenomena in a holistic approach. The reliability assessment of an existing reinforced concrete bridge subjected to increasing traffic demand and spatially-variable pitting corrosion is investigated. Empirical data are used to develop probabilistic models for cracking initiation, pitting factor, severe cracking, and cover spalling.
Statistical distributions of temperatures from a local meteorological station are used to investigate environmental effects on corrosion initiation. For the traffic, national highway databases are used to model the vehicular flow. Ductile and brittle failure mechanics are considered for the structural capacity assessment. Coupled biaxial bending-axial loading domain is adopted for the ductile structural checks. The shear capacity is assessed through the response limit surface from the modified compression field theory results. Finally, Monte Carlo simulations are performed at intervals of 10 years to derive a time-dependent reliability profile compared against standard thresholds to determine the health conditions of the bridge.
Statistical distributions of temperatures from a local meteorological station are used to investigate environmental effects on corrosion initiation. For the traffic, national highway databases are used to model the vehicular flow. Ductile and brittle failure mechanics are considered for the structural capacity assessment. Coupled biaxial bending-axial loading domain is adopted for the ductile structural checks. The shear capacity is assessed through the response limit surface from the modified compression field theory results. Finally, Monte Carlo simulations are performed at intervals of 10 years to derive a time-dependent reliability profile compared against standard thresholds to determine the health conditions of the bridge.
Original language | English |
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Article number | 108137 |
Number of pages | 20 |
Journal | Reliability Engineering and System Safety |
Volume | 218 |
Issue number | A |
Early online date | 28 Oct 2021 |
DOIs | |
Publication status | Published - 1 Feb 2022 |
Bibliographical note
Funding Information:The authors would like to acknowledge the gracious support of this work through the EPSRC and ESRC Centre for Doctoral Training on Quantification and Management of Risk and Uncertainty in Complex Systems Environments Grant No. (EP/L015927/1). The second author is supported by the Engineering and Physical Sciences Research Council (EPSRC) project UKCRIC (EP/R012806/1). This work was undertaken on Barkla, part of the High-Performance Computing facilities at the University of Liverpool, UK, and using the computational facilities of the Advanced Computing Research Center, University of Bristol ( http://www.bris.ac.uk/acrc/ ).
Funding Information:
The authors would like to acknowledge the gracious support of this work through the EPSRC and ESRC Centre for Doctoral Training on Quantification and Management of Risk and Uncertainty in Complex Systems Environments Grant No. (EP/L015927/1). The second author is supported by the Engineering and Physical Sciences Research Council (EPSRC) project UKCRIC (EP/R012806/1). This work was undertaken on Barkla, part of the High-Performance Computing facilities at the University of Liverpool, UK, and using the computational facilities of the Advanced Computing Research Center, University of Bristol (http://www.bris.ac.uk/acrc/).
Publisher Copyright:
© 2021 Elsevier Ltd
Keywords
- Reliability Assessment
- Corrosion
- Probabilistic Modelling
- Traffic loading
- Bridge Engineering
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Alam, S. R. (Manager), Eccleston, P. E. (Other), Williams, D. A. G. (Manager) & Atack, S. H. (Other)
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