Predicting long-term tensile degradation of GFRP rebars embedded in concrete with a reconsidered environmental reduction factor CE
Glass fiber reinforced polymer (GFRP) has been considered as an advanced material to replace conventional steel reinforcements in concrete structures to address the corrosion issue. The degradation of GFRP rebars, which may threaten both the durability and safety of infrastructures, is a major conce...
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| Published in | Developments in the built environment Vol. 20; p. 100583 |
|---|---|
| Main Authors | , , , , , , |
| Format | Journal Article |
| Language | English |
| Published |
Elsevier Ltd
01.12.2024
Elsevier |
| Subjects | |
| Online Access | Get full text |
| ISSN | 2666-1659 2666-1659 |
| DOI | 10.1016/j.dibe.2024.100583 |
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| Abstract | Glass fiber reinforced polymer (GFRP) has been considered as an advanced material to replace conventional steel reinforcements in concrete structures to address the corrosion issue. The degradation of GFRP rebars, which may threaten both the durability and safety of infrastructures, is a major concern. To predict the 100-year strength retention of GFRP under various temperature and relative humidity conditions, the environmental reduction factor (CE) is applied in engineering. The conventional CE based on the assumption of logarithmic degradation model is commonly utilized during the degradation phase spanning from a few years to decades; however, it is not applicable to the initial and perpetual degradation phases. To address this issue, a novel environmental reduction factor (CE′) based on the exponential degradation model considering temperature and relative humidity is proposed in this study. Both CE and CE′ are mathematically deduced from empirical degradation data and then evaluated in a case study involving GFRP-concrete samples soaked in water at 23, 40 or 60 °C for up to 12 months within the authors’ dataset. Experimental results show that the GFRP tensile strength degradation is closer to the exponential model, reaching a plateau (47.4%) after 12-month exposure to 60 °C water. Moreover, the tensile strength retention of GFRP rebars in Vancouver (10 °C), Shanghai (16 °C) and Houston (22 °C) is predicted considering various scenarios of relative humidities (0–90%). Further research indicates that CE′ (0.65–0.78) exhibits a smaller value compared to CE (0.81) at a temperature of 22 °C and a relative humidity of 90% following a 100-year exposure period, thereby providing engineers with a more conservative design approach for GFRP in real-world scenarios. Nevertheless, this exponential degradation model requires a thorough consideration of severe degradation state during the extended aging period, which may not be applicable to GFRP structures exhibiting exceptional durability.
•Reduction factor enhance GFRP strength prediction, surpassing conventional method.•Degradation trend through empirical analysis, providing insights for long-term integrity.•Revelation of relative humidity's significant influence on GFRP strength degradation.•Implications of reduction factor ensure the structural reliability of GFRP in harsh conditions. |
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| AbstractList | Glass fiber reinforced polymer (GFRP) has been considered as an advanced material to replace conventional steel reinforcements in concrete structures to address the corrosion issue. The degradation of GFRP rebars, which may threaten both the durability and safety of infrastructures, is a major concern. To predict the 100-year strength retention of GFRP under various temperature and relative humidity conditions, the environmental reduction factor (CE) is applied in engineering. The conventional CE based on the assumption of logarithmic degradation model is commonly utilized during the degradation phase spanning from a few years to decades; however, it is not applicable to the initial and perpetual degradation phases. To address this issue, a novel environmental reduction factor (CE′) based on the exponential degradation model considering temperature and relative humidity is proposed in this study. Both CE and CE′ are mathematically deduced from empirical degradation data and then evaluated in a case study involving GFRP-concrete samples soaked in water at 23, 40 or 60 °C for up to 12 months within the authors’ dataset. Experimental results show that the GFRP tensile strength degradation is closer to the exponential model, reaching a plateau (47.4%) after 12-month exposure to 60 °C water. Moreover, the tensile strength retention of GFRP rebars in Vancouver (10 °C), Shanghai (16 °C) and Houston (22 °C) is predicted considering various scenarios of relative humidities (0–90%). Further research indicates that CE′ (0.65–0.78) exhibits a smaller value compared to CE (0.81) at a temperature of 22 °C and a relative humidity of 90% following a 100-year exposure period, thereby providing engineers with a more conservative design approach for GFRP in real-world scenarios. Nevertheless, this exponential degradation model requires a thorough consideration of severe degradation state during the extended aging period, which may not be applicable to GFRP structures exhibiting exceptional durability.
•Reduction factor enhance GFRP strength prediction, surpassing conventional method.•Degradation trend through empirical analysis, providing insights for long-term integrity.•Revelation of relative humidity's significant influence on GFRP strength degradation.•Implications of reduction factor ensure the structural reliability of GFRP in harsh conditions. Glass fiber reinforced polymer (GFRP) has been considered as an advanced material to replace conventional steel reinforcements in concrete structures to address the corrosion issue. The degradation of GFRP rebars, which may threaten both the durability and safety of infrastructures, is a major concern. To predict the 100-year strength retention of GFRP under various temperature and relative humidity conditions, the environmental reduction factor (CE) is applied in engineering. The conventional CE based on the assumption of logarithmic degradation model is commonly utilized during the degradation phase spanning from a few years to decades; however, it is not applicable to the initial and perpetual degradation phases. To address this issue, a novel environmental reduction factor (CE′) based on the exponential degradation model considering temperature and relative humidity is proposed in this study. Both CE and CE′ are mathematically deduced from empirical degradation data and then evaluated in a case study involving GFRP-concrete samples soaked in water at 23, 40 or 60 °C for up to 12 months within the authors’ dataset. Experimental results show that the GFRP tensile strength degradation is closer to the exponential model, reaching a plateau (47.4%) after 12-month exposure to 60 °C water. Moreover, the tensile strength retention of GFRP rebars in Vancouver (10 °C), Shanghai (16 °C) and Houston (22 °C) is predicted considering various scenarios of relative humidities (0–90%). Further research indicates that CE′ (0.65–0.78) exhibits a smaller value compared to CE (0.81) at a temperature of 22 °C and a relative humidity of 90% following a 100-year exposure period, thereby providing engineers with a more conservative design approach for GFRP in real-world scenarios. Nevertheless, this exponential degradation model requires a thorough consideration of severe degradation state during the extended aging period, which may not be applicable to GFRP structures exhibiting exceptional durability. |
| ArticleNumber | 100583 |
| Author | Wang, Peng Ke, Linyuwen Zhou, Yajie Lu, Yao Li, Weiwen Wu, Haoliang Leung, Christopher K.Y. |
| Author_xml | – sequence: 1 givenname: Peng surname: Wang fullname: Wang, Peng organization: Guangdong Provincial Key Laboratory of Durability for Marine Civil Engineering, Shenzhen University, Shenzhen, China – sequence: 2 givenname: Yajie surname: Zhou fullname: Zhou, Yajie organization: Guangdong Provincial Key Laboratory of Durability for Marine Civil Engineering, Shenzhen University, Shenzhen, China – sequence: 3 givenname: Yao surname: Lu fullname: Lu, Yao organization: Guangdong Provincial Key Laboratory of Durability for Marine Civil Engineering, Shenzhen University, Shenzhen, China – sequence: 4 givenname: Linyuwen surname: Ke fullname: Ke, Linyuwen organization: College of Civil Engineering and Architecture, Jiaxing University, Jiaxing, 314001, China – sequence: 5 givenname: Haoliang surname: Wu fullname: Wu, Haoliang email: wuhliang5@mail.sysu.edu.cn organization: School of Civil Engineering, Sun Yat−sen University & Southern Marine Science and Engineering Guangdong Laboratory (Zhuhai), Zhuhai, 519082, China – sequence: 6 givenname: Weiwen surname: Li fullname: Li, Weiwen organization: Guangdong Provincial Key Laboratory of Durability for Marine Civil Engineering, Shenzhen University, Shenzhen, China – sequence: 7 givenname: Christopher K.Y. surname: Leung fullname: Leung, Christopher K.Y. organization: Department of Civil and Environmental Engineering, Hong Kong University of Science and Technology, Hong Kong SAR, China |
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| Keywords | Degradation Relative humidity Environmental reduction factor Durability Glass fiber reinforced polymer |
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| Title | Predicting long-term tensile degradation of GFRP rebars embedded in concrete with a reconsidered environmental reduction factor CE |
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