Research on the Bonding Performance of BFRP Bars with Reactive Powder Concrete

Xiao, Jie; Murong, Yikang; Chen, Xiyuan; Liu, Lingfei; Zhai, Keyi; Jiang, Haibo; Huang, Linhai; Wang, Guodong

doi:10.3390/buildings13082083

Cited by 3 publications

(1 citation statement)

References 34 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Shatha D. Mohammed [15] provides an experimental analysis of the structural behaviors of reinforced RPC beams under harmonic loads, in which the outcomes proved the positive effect of adding steel fibers on the dynamic response under the effect of harmonic loading in RPC. Jie Xiao [16] carried out a study to solve the problem of steel bars in ordinary reinforced concrete structures by replacing steel bars with basalt fiber-reinforced polymer bars and replacing ordinary concrete with reactive powder concrete, considering the law of bond strength and protective layer thickness.…”

Section: Introductionmentioning

confidence: 99%

Study on the Mechanical Performance of RC Beams under Load Reinforced by a Thin Layer of Reactive Powder Concrete on Four Sides

Liao,

Yang,

Yang

2024

Buildings

View full text Add to dashboard Cite

To repair reinforced concrete beams efficiently in a limited building space, the four-sided application of a reinforcing thin layer of reactive powder concrete (“RPCTL”) was proposed to improve the bending capacity of the members. Static flexural tests of one comparison beam and five reinforced beams were completed on a four-point centralized loading device. Changes in deflection, cracks, stresses, and damage characteristics of the specimens were measured under various levels of loading. The test results showed that the damage patterns of the reinforced specimens were dominated by the yielding of longitudinal tensile reinforcement at the bottoms of the beams and the crushing of the cementitious material in the top compression zones of the beams. The cracking load greatly increased by 1.42 to 7.12 times, and the ultimate bearing capacity increased by 0.29 to 1.41 times. The distribution characteristics and dynamic changes in the displacement, stress, and damage of the specimens were dynamically simulated by finite element software. The effects of reinforcement and initial load-holding level on the reinforcement effect were investigated. A bending capacity calculation formula for RPCTL reinforcement technology is proposed that aligns with the test results and can provide a reference for the design of RPCTL reinforcement.

show abstract

Section: Introductionmentioning

confidence: 99%