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Reliability analysis for the existing reinforced concrete pile corrosion of bridge substructure
AbstractThis study investigated the failure probability for existing reinforced concrete (RC) pile corrosion due to carbonation, chloride ion ingress and sulfate attack combined with the load-carrying capacity for bridge substructures at different amounts of service times. The general corrosion resulted from carbonation, the pitting corrosion occurred from chloride ion ingress, and the chemical mechanism due to sulfate attack to the existing RC piles of a bridge substructure is described. Both the theory of structural joint failure probability and the measurement techniques of carbonation depth, chloride ion ingress depth, and sulfate expansion are also provided. An existing RC bridge pile with a service time of 60 years is offered as an example for illustrating the structural joint failure probability theory. The structural joint failure probability of existing RC bridge piles due to the combination of carbonation, chloride ion ingress, sulfate attack, and load-carrying capacity at a service time of 60 years had lower and upper bound values of .440382 and .502755, respectively. These results are provided as a critical decision-making for the repair, strengthening, or demolition of existing RC bridge substructure pile foundations.
Reliability analysis for the existing reinforced concrete pile corrosion of bridge substructure
AbstractThis study investigated the failure probability for existing reinforced concrete (RC) pile corrosion due to carbonation, chloride ion ingress and sulfate attack combined with the load-carrying capacity for bridge substructures at different amounts of service times. The general corrosion resulted from carbonation, the pitting corrosion occurred from chloride ion ingress, and the chemical mechanism due to sulfate attack to the existing RC piles of a bridge substructure is described. Both the theory of structural joint failure probability and the measurement techniques of carbonation depth, chloride ion ingress depth, and sulfate expansion are also provided. An existing RC bridge pile with a service time of 60 years is offered as an example for illustrating the structural joint failure probability theory. The structural joint failure probability of existing RC bridge piles due to the combination of carbonation, chloride ion ingress, sulfate attack, and load-carrying capacity at a service time of 60 years had lower and upper bound values of .440382 and .502755, respectively. These results are provided as a critical decision-making for the repair, strengthening, or demolition of existing RC bridge substructure pile foundations.
Reliability analysis for the existing reinforced concrete pile corrosion of bridge substructure
Liang, Ming-Te (author) / Lan, Ji-Jie (author)
Cement and Concrete Research ; 35 ; 540-550
2004-05-05
11 pages
Article (Journal)
Electronic Resource
English
Carbonation , Corrosion , Degradation , Expansion , Reaction
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