Experimental study on the mechanical and self-sensing behaviors of prestressed carbon fiber–reinforced polymer reinforced concrete composite structures

Wang, Guan; Yang, Caiqian; Chun-lin, Meng; Xia, Z.; Pan, Yong; Wang, Mengwei

doi:10.1177/1369433219895915

Cited by 10 publications

(4 citation statements)

References 39 publications

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“…El sistema de anclaje juega un papel vital en las estructuras reforzadas con PRF y se han desarrollado varios tipos de sistemas de anclaje, por lo cual el refuerzo en una placa de concreto armado es más eficaz debido a su mayor grosor, sin embargo, esto origina que sea difícil de fijarse en la placa de concreto armado [10] .…”

Section: Metodologíaunclassified

Uso de PRFC para mejorar las propiedades mecánicas del concreto: una revisión

Pérez

Chunga

Rafael

2021

CULCYT

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El polímero reforzado con fibra de carbono (PRFC) hoy en día se ha vuelto una alternativa de material de fortalecimiento para las estructuras en la construcción porque mejora las propiedades mecánicas del concreto y aunque es un proceso de fabricación de costo elevado, origina un gran beneficio para la estructura de concreto armado (CA). El objetivo de este trabajo ha sido revisar la investigación notable publicada en revistas indexadas de los años 2012 a 2021 (41 artículos de Scopus, 7 de EBSCO, 2 de Science Direct y 1 de Redalyc), sobre el uso del polímero reforzado con fibra de carbono en elementos estructurales, como reforzamiento interno o externo, que beneficia a la estructura en su periodo de vida, al impacto ambiental que este produce, al costo del material y al manejo del material in situ.

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Section: Metodologíaunclassified

Uso de PRFC para mejorar las propiedades mecánicas del concreto: una revisión

Pérez

Chunga

Rafael

2021

CULCYT

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“…34 Other fatigue experiments on prestressed concrete beams under multi-level incremental amplitude cyclic loading were conducted, and the method of predicting their fatigue life was also put forward to fulfill the study database of fatigue properties. 35 More recently, studies on damaged concrete beams and strengthened beams have shown that the fatigue life degrades dramatically on an increase of loading amplitude. 36,37 Furthermore, from the tests on RC beams under coupling action of hot-wet environment and variable amplitude overload, it is concluded that a relatively high load level exacerbates the crack propagation of tensile rebars, which results in earlier fracture of rebars and further failure of strengthened beams.…”

Section: Introductionmentioning

confidence: 99%

“…Based on fatigue tests of concrete beams under two‐stage variable amplitude cyclic loading, the predictive fatigue life was more accurate by the method of residual strength criterion rather than by original Miner damage rule 34 . Other fatigue experiments on prestressed concrete beams under multi‐level incremental amplitude cyclic loading were conducted, and the method of predicting their fatigue life was also put forward to fulfill the study database of fatigue properties 35 . More recently, studies on damaged concrete beams and strengthened beams have shown that the fatigue life degrades dramatically on an increase of loading amplitude 36,37 .…”

Section: Introductionmentioning

confidence: 99%

Interfacial properties of CFRP sheets and concrete subjected to variable amplitude fatigue loading

Yuan

Luo

Liu

et al. 2021

Structural Concrete

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In order to better understand the interfacial fatigue behavior of concrete and fiber-reinforced polymer (FRP), bending fatigue tests were conducted on plain concrete beams strengthened with carbon FRP (CFRP) sheets under variable amplitude cyclic loading which deteriorates structural performance in actual projects more dramatically than constant amplitude loading. The test parameters were four types of loading modes including static loading, constant amplitude cyclic loading, alternating amplitude cyclic loading and incremental amplitude cyclic loading. Miner damage rule, modified Miner damage rule and Corten-Dolan cumulative damage rule were used to predict the fatigue life of specimens. The relationship between loads and deflections, the relationship between strains and cycle times and the crack propagation were analyzed. The results have shown that the fatigue life of specimens under variable amplitude cyclic loading, especially alternating one, is shorter than that of specimens under constant one, and the modified Miner damage rule is more suitable to predict fatigue life. The crack lengths on the lateral faces of beams recorded by digital image correlation (DIC) method developed more slowly than those at the bottom sides recorded by strain gauges. A proposed damage model describing the relationship between the crack lengths and fatigue life for specimens under alternating amplitude fatigue loading is consistent with the experimental results well. K E Y W O R D Scarbon fiber reinforced polymer (CFRP), concrete reinforcement, crack length, interfacial properties, variable amplitude fatigue loading

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“…By including up to 1.5% more steel fibres, the mechanical properties can be improved. When compared to glass fibre-reinforced concrete, the inclusion of 1.5% steel wires produces better outcomes [10]. The concrete of grade M30 will produce 10% greater compressive strength after 28 days of curing by adding waste metal scrap as a reinforced fibres to the concrete.…”

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confidence: 99%

An experimental investigation of Marble Powder as a Partial Replacement of cement and Waste Metal Scrap as Reinforcing Material on the Mechanical Characteristics of Concrete

Tiwari,

Yadav,

Bano

2024

IOP Conf. Ser.: Earth Environ. Sci.

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To conduct the study, the researchers incorporated marble powder into the cement at varying proportions: 0%, 5%, 10%, and 15% by weight of the cement. This led to the creation of concrete with a M35-grade classification. After the concrete samples were given 7, 14, and 28 days to cure, several tests were performed to evaluate their flexural strength, compression strength, and split tensile strength. The experimental investigations demonstrated that the mechanical properties of the concrete specimens exhibited an initial enhancement when the cement weight was substituted with marble powder up to a 10% replacement, after which they began to decline. However, the inclusion of metal scrap in addition to marble powder showed positive effects on the strength properties. This finding indicates that the incorporation of both marble powder and metal scrap in concrete can effectively improve its mechanical strength. Furthermore, the researchers examined the microstructural properties of marble powder through the utilization of advanced methodologies such as Scanning Electron Microscopy (SEM) and Energy-Dispersive X-ray Spectroscopy (EDX)). The research findings indicated that the most optimum combination for attaining the maximum mechanical strength, in comparison to traditional concrete, involved incorporating 0.75% metal scrap and replacing 10% of the cement with marble powder. Beyond this proportion, a substantial reduction in strength was seen. The results also showed that incorporating a certain amount of marble powder with metal scrap led to improved interlocking of the aggregates, resulting in increased durability compared to traditional cement concrete.

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Experimental study on the mechanical and self-sensing behaviors of prestressed carbon fiber–reinforced polymer reinforced concrete composite structures

Cited by 10 publications

References 39 publications

Uso de PRFC para mejorar las propiedades mecánicas del concreto: una revisión

Uso de PRFC para mejorar las propiedades mecánicas del concreto: una revisión

Interfacial properties of CFRP sheets and concrete subjected to variable amplitude fatigue loading

An experimental investigation of Marble Powder as a Partial Replacement of cement and Waste Metal Scrap as Reinforcing Material on the Mechanical Characteristics of Concrete

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