Hysteretic model for corroded reinforced concrete columns retrofitted with FRP-CSCIED科技核心评价数据库-手机版

Hysteretic model for corroded reinforced concrete columns retrofitted with FRP

Hysteretic model for corroded reinforced concrete columns retrofitted with FRP

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DOI	https://doi.org/10.1016/j.conbuildmat.2023.131207
刊名	Construction and Building Materials
年，卷(期)	2023, (131207)
作者	Kuangyu Dai, Xiaohui Yu, Zhichao Jiang, Daiyu Wang, Kai Qian,
作者单位	1.School of Hydraulic and Civil Engineering, Zhengzhou University, 450001, China 2.College of Civil Engineering and Architecture, Guilin University of Technology, 541004, China 3.School of Civil Engineering, Harbin Institute of Technology, 150090, China
摘要	A hysteresis model was developed for fiber reinforced polymer (FRP)-retrofitted reinforced concrete (RC) columns with corroded reinforcing bars. The test data of 49 FRP-retrofitted corroded columns and 19 intact columns (with no corrosion or FRP wraps) under repeat-cyclic loading were collected to establish a database. A polygonal model was adopted to simulate the hysteretic behavior of FRP-retrofitted corroded columns. This was determined using backbone and cyclic parameters. For the backbone parameters, a hybrid influence factor (HIF) was introduced to incorporate the coupling effects of corrosion and FRP retrofitting. A suite of empirical equations was developed using multivariate linear regression analysis to predict the HIFs of each backbone parameter in association with the corrosion rate and important column design parameters. Moreover, an empirical relationship was developed to determine the cyclic parameters of the hysteretic model using a regression analysis. The predicted hysteretic curves were compared with the experimental results, demonstrating sufficient accuracy for both intra- and extra-database tests. Finally, the developed hysteretic model was used to establish a macro-type structural model for the FRP-retrofitted corroded RC frames. This benefitted the analysis of structural collapse under earthquakes, and the effects of the corrosion rate and FRP retrofitting schemes on the seismic collapse capacity of RC frames were examined.
Abstract	A hysteresis model was developed for fiber reinforced polymer (FRP)-retrofitted reinforced concrete (RC) columns with corroded reinforcing bars. The test data of 49 FRP-retrofitted corroded columns and 19 intact columns (with no corrosion or FRP wraps) under repeat-cyclic loading were collected to establish a database. A polygonal model was adopted to simulate the hysteretic behavior of FRP-retrofitted corroded columns. This was determined using backbone and cyclic parameters. For the backbone parameters, a hybrid influence factor (HIF) was introduced to incorporate the coupling effects of corrosion and FRP retrofitting. A suite of empirical equations was developed using multivariate linear regression analysis to predict the HIFs of each backbone parameter in association with the corrosion rate and important column design parameters. Moreover, an empirical relationship was developed to determine the cyclic parameters of the hysteretic model using a regression analysis. The predicted hysteretic curves were compared with the experimental results, demonstrating sufficient accuracy for both intra- and extra-database tests. Finally, the developed hysteretic model was used to establish a macro-type structural model for the FRP-retrofitted corroded RC frames. This benefitted the analysis of structural collapse under earthquakes, and the effects of the corrosion rate and FRP retrofitting schemes on the seismic collapse capacity of RC frames were examined.
关键词	Hysteretic model；FRP；Corrosion of reinforcing bar；Reinforced concrete column；Collapse analysis
KeyWord	Hysteretic model；FRP；Corrosion of reinforcing bar；Reinforced concrete column；Collapse analysis
基金项目
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引用本文

Kuangyu Dai, Xiaohui Yu, Zhichao Jiang, Daiyu Wang, Kai Qian. Hysteretic model for corroded reinforced concrete columns retrofitted with FRP [J]. Construction and Building Materials. 2023; ; (131207). - .

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