Flexural Performance of Hybrid Engineered Cementitious Composite Layered Reinforced Concrete Beams

Krishnaraja, A. R.; Kandasamy, Shanmughasundaram

doi:10.3311/ppci.11748

Cited by 22 publications

(22 citation statements)

References 27 publications

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“…Because if a good connection is established at the joint surface of the jacket and the primary column, the behavior of the reinforced column will be closer to the behavior of the integrated specimen. Krishnaraja and Kandasamy [29] have evaluated the effect of ECC layers on concrete beams, which is similar to the purpose of this research. They have concluded that compared with the conventional concrete beam, the ECC layer presence not only leads to significant enhancement in the cracking load, yielding load and ultimate load but also increases the load-bearing capacity, deflection, energy absorption, and ductility due to strain hardening of ECC layer in the concrete beam.…”

Section: Introductionmentioning

confidence: 87%

Experimental and Numerical Investigation of Different Types of Jacketing Effect on Retrofitting RC Short Columns Using ECC Concrete

Dadmand

Pourbaba

Riahi

2022

Period. Polytech. Civil Eng.

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Given the deterioration of civil infrastructure throughout the world, developing more efficient repair and strengthening is essential. Jacketing is one of the most common methods for retrofitting reinforced concrete (RC) columns. Notably, using engineered cementitious composite (ECC) within the jacketing area increases the bearing capacity and significantly enhances the ductility of the columns. The recent development of ECC concrete with suitable compressive strength and higher ductility of about 5 % can significantly enhance the performance of reinforced concrete structures. The behavior of retrofitted RC columns depends heavily on the cohesion between the jacket and the original column as well as the mechanical properties of the jacketing materials. This study investigates jacketed square and circular RC columns using ECC and conventional/normal concrete (NC) using different casing techniques to retrofit RC columns, namely galvanized mesh, U and L-shape joints, removing the cover, core drilling, and integrated models. All specimens were subjected to a compression test. The results indicate that in both square and circular specimens, the use of ECC as a super ductile material and vertical U-shaped elements to connect the longitudinal rebars of the casing and the core leads to much higher ductility and bearing capacity than in NC specimens. These elements also showed suitable ductility because of using ECC as a super ductile material. In order to optimize these methods, finite element analysis (FEA) was conducted using Abaqus software to verify experimental models, as well as a parametric study to achieve an optimum design of the jacketing.

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Section: Introductionmentioning

confidence: 87%

Experimental and Numerical Investigation of Different Types of Jacketing Effect on Retrofitting RC Short Columns Using ECC Concrete

Dadmand

Pourbaba

Riahi

2022

Period. Polytech. Civil Eng.

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“…From results, it was found that CFST beam with 2% steel fiber volume fraction carries the maximum load with notable deflection due to high modulus of rigidity of fiber [23]. However, the energy absorption capacity of CFST beam with 2% of polypropylene fiber is high when compare with other beams because the polypropylene fiber is a low modulus fiber and which exhibits high elongation with minimum load carrying capacity [24]. Mix M10 and M13 absorb notable load than the M5 mix, but it fails to perform in the deformation.…”

Section: Flexural Performance Of Composite Beammentioning

confidence: 96%

Behaviour of hybrid fibre reinforced concrete-filled steel tubular beams and columns

Kathiresan¹,

Govindasamy

2020

Matéria (Rio J.)

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This paper presents the flexural performance of newly developed hybrid fiber reinforced concrete-filled steel tubular sections. The test parametres are fiber volume fraction and fiber hybridation ratio. Initially mechanical properties studied for 10 mono fiber reinforced concrete mixes using steel and Polypropylene fibres with 0.5%, 1.0%, 1.5%, 2.0% and 2.5% volume fraction. Based on the performance optimum fiber dosage was determined in each fiber, with the same volume fraction three different fiber hybridation was developed. Developed hybrid fiber reinforcement concrete, conventional concrete and optimum mono fiber reinforced concrete was used in the concrete-filled steel tubular beams and columns to determine the structural performance. The test results shows that, fiber reinforced concrete-filled steel tubular beams display significant improvement in the flexural performance.

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“… Ductility of repaired RC beam is 71-263% higher than the control specimen. [18] 150x230x1800 or 150x260x1800…”

Section: Performance Of Geopolymer-strengthened Concrete Beammentioning

confidence: 99%

“…Applying a 25 mm thick SFRG repair material improved the ductility value of the RC beam by at least 7% [17]. On the other hand, using 30 mm thick SFRG repair layer increased the ductility of the strengthened RC beam by 360% [18]. Generally, the increase in ductility would also result to higher toughness or energy absorption capacity of the strengthened beams.…”

Section: Performance Of Geopolymer-strengthened Concrete Beammentioning

confidence: 99%

Structural Performance of Concrete Elements Retrofitted by a Geopolymer Strengthening System: Input in the Rehabilitation of Historical Buildings

Guades¹,

Stang²

2019

WIT Transactions on the Built Environment

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Rehabilitation of historic buildings is a priority since their structural elements suffered from various levels of damage that took place during their service life. Recently, geopolymer is gaining acceptance as an emerging material in the construction industry due to its added advantages. It has shown excellent bond strength to concrete substrate, lower creep and shrinkage, greater durability in severe environments and higher temperature and fire resistance. Geopolymer is relatively new in the rehabilitation system of building structures, although it had been used for new construction applications. Therefore, an effort was made to gather information on the use of geopolymer as repair and strengthening material. This paper reviewed the structural performance of geopolymer-strengthened concrete elements and the field applications of geopolymer as strengthening material for historical buildings. Information from the literature revealed that the load capacity of the non-damaged and fully damaged reinforced concrete (RC) beam can be increased by 12% and 100%, respectively, when strengthened using plain geopolymer. It was found that short fiber-reinforced geopolymer (SFRG) strengthening system enhanced the peak load of RC beam by 15% while 370% if using continuous fiber-reinforced geopolymer (CFRG). To date, field applications of geopolymer strengthening system on historical buildings were limited, nevertheless this technique provided good structural performance making it suitable in the rehabilitation process.

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Flexural Performance of Hybrid Engineered Cementitious Composite Layered Reinforced Concrete Beams

Cited by 22 publications

References 27 publications

Experimental and Numerical Investigation of Different Types of Jacketing Effect on Retrofitting RC Short Columns Using ECC Concrete

Experimental and Numerical Investigation of Different Types of Jacketing Effect on Retrofitting RC Short Columns Using ECC Concrete

Behaviour of hybrid fibre reinforced concrete-filled steel tubular beams and columns

Structural Performance of Concrete Elements Retrofitted by a Geopolymer Strengthening System: Input in the Rehabilitation of Historical Buildings

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