碳化作用
纤维增强塑料
材料科学
腐蚀
水分
使用寿命
岩土工程
结构工程
降级(电信)
氯化物
钢筋混凝土
环境科学
脆性
自然(考古学)
腐蚀
抗剪强度(土壤)
领域(数学)
剪切(地质)
可用的
海水
土木工程
复合材料
耐久性
作者
Qi Zhao,Keitai Iwama,Jian‐Guo Dai,Daxu Zhang,Xuan Zhao,Haien Xue,Koichi Maekawa,Xiao‐Ling Zhao
标识
DOI:10.1061/jccof2.cceng-5349
摘要
This paper proposes a theoretical framework for analyzing the in-service performance degradation of fiber-reinforced polymer (FRP)–reinforced concrete structures exposed to natural marine environments, focusing on the deterioration of concrete and its FRP reinforcements. First, multiscale physicochemo-coupled modeling was employed to evaluate the moisture transport, heat transfer, chloride penetration, and carbonation in concrete structures exposed to marine atmospheric environments. Subsequently, based on the dynamic internal concrete environments (i.e., temperature, RH, pH, and chloride concentration) obtained previously, a chemical etching–based model and the gas–liquid state shift theory were applied to calculate the erosion depth and horizontal shear strength of FRP bars embedded in concrete. Finally, based on the periodical weather data, the long-term performance degradation of FRP reinforcements within concrete was projected over decades of service. The proposed approach offers significant potential for evaluating the time-dependent service performance of FRP-marine concrete infrastructures, with validations by a case study, the glass FRP–reinforced concrete dry dock in Hawaii using field data after 18 years of service.
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