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Flexural strengthening of damaged steel beams with prestressed CFRP plates using a novel prestressing system
Highlights A new prestressing system of the CFRP plate is developed to strengthen steel beams. The steel beams are strengthened with bonded and unbonded prestressed CFRP plates. The bonded and unbonded CFRP strengthening methods provide a close efficacy. Applying prestress is more effective than only increasing CFRP thickness or modulus. The strengthening efficiency increases with artificial notch depth.
Abstract This study developed a novel prestressing system of the carbon fiber reinforced polymer (CFRP) plate to strengthen damaged steel beams, which reduced the operation space at the tensioning end, thereby extending the application range of prestressing system. Flexural tests were conducted to verify this system and investigate the effects of the adhesive layer, prestressing level, and CFRP plate area on the strengthening efficiency, and subsequently, a parametric analysis was carried out using finite element modeling to obtain more influencing rules of the unbonded CFRP plate-strengthened steel beams. The results indicated that satisfactory strengthening efficiency could be achieved by the novel prestressing system. The adhesive layer significantly affected the strain distributions of the steel–CFRP composite section, whereas it had a very slight effect on the flexural behavior of the steel beams, and the bonded and unbonded CFRP plates had a similar strengthening efficiency. Nonprestressed CFRP plate exhibited limited improvement in the flexural capacity and stiffness of the damaged steel beams under the normal service state; in contrast, the prestressed CFRP significantly increased the flexural behavior of the beams in the elastic and elastic–plastic stages owing to the high strength utilization of the CFRP plate. In addition, as the prestressing level increased, strengthening efficiency increased. Solely increasing the area or elastic modulus of the CFRP plate improved the strengthening efficiency slightly, whereas applying a prestress simultaneously clearly increases the strengthening efficiency. The strengthening efficiency increases with artificial notch depth.
Flexural strengthening of damaged steel beams with prestressed CFRP plates using a novel prestressing system
Highlights A new prestressing system of the CFRP plate is developed to strengthen steel beams. The steel beams are strengthened with bonded and unbonded prestressed CFRP plates. The bonded and unbonded CFRP strengthening methods provide a close efficacy. Applying prestress is more effective than only increasing CFRP thickness or modulus. The strengthening efficiency increases with artificial notch depth.
Abstract This study developed a novel prestressing system of the carbon fiber reinforced polymer (CFRP) plate to strengthen damaged steel beams, which reduced the operation space at the tensioning end, thereby extending the application range of prestressing system. Flexural tests were conducted to verify this system and investigate the effects of the adhesive layer, prestressing level, and CFRP plate area on the strengthening efficiency, and subsequently, a parametric analysis was carried out using finite element modeling to obtain more influencing rules of the unbonded CFRP plate-strengthened steel beams. The results indicated that satisfactory strengthening efficiency could be achieved by the novel prestressing system. The adhesive layer significantly affected the strain distributions of the steel–CFRP composite section, whereas it had a very slight effect on the flexural behavior of the steel beams, and the bonded and unbonded CFRP plates had a similar strengthening efficiency. Nonprestressed CFRP plate exhibited limited improvement in the flexural capacity and stiffness of the damaged steel beams under the normal service state; in contrast, the prestressed CFRP significantly increased the flexural behavior of the beams in the elastic and elastic–plastic stages owing to the high strength utilization of the CFRP plate. In addition, as the prestressing level increased, strengthening efficiency increased. Solely increasing the area or elastic modulus of the CFRP plate improved the strengthening efficiency slightly, whereas applying a prestress simultaneously clearly increases the strengthening efficiency. The strengthening efficiency increases with artificial notch depth.
Flexural strengthening of damaged steel beams with prestressed CFRP plates using a novel prestressing system
Wang, Hai-Tao (author) / Bian, Zhi-Ning (author) / Chen, Min-Sheng (author) / Hu, Lili (author) / Wu, Qiong (author)
Engineering Structures ; 284
2023-03-05
Article (Journal)
Electronic Resource
English
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