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Optimal FRP-strengthening strategy for corrosion-affected reinforced concrete columns
Deterioration of reinforced concrete (RC) structures is unavoidable after their long time in service, with corrosion being the major mechanism of deterioration. In order to ensure safety of deteriorated structures, an effective rehabilitation plan is essential. Although considerable research on strengthening of RC structures using fibre-reinforced polymers (FRPs) composites has been undertaken, more is on the methods of strengthening and effects of corrosion on strength of RC columns than that on the prediction of optimum strengthening time. This paper presents a methodology for determining the optimal strengthening time and the required number of FRP layers for corrosion-affected RC structures with application to columns. The methodology is based on the time-dependent reliability method and the renewal theory. An example is provided to illustrate the application of the proposed methodology. It is found in this study that an optimum point for the formulated objective function exists, and that outcomes of optimisation problem, i.e. strengthening time and number of required FRP layers, are sensitive to corrosion rate. The significance of the proposed methodology is that it provides guidance for practitioners and asset managers to decide when and how to strengthen deteriorated structural members. © 2018, © 2018 Informa UK Limited, trading as Taylor & Francis Group.
Funding
Category 1 - Australian Competitive Grants (this includes ARC, NHMRC)
History
Volume
14Issue
12Start Page
1586End Page
1597Number of Pages
12eISSN
1744-8980ISSN
1573-2479Publisher
Taylor & Francis, UKPublisher DOI
Peer Reviewed
- Yes
Open Access
- No
Acceptance Date
2018-02-20External Author Affiliations
RMIT University; Victoria UniversityEra Eligible
- Yes
Journal
Structure and Infrastructure EngineeringUsage metrics
Keywords
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