Effects of Low Temperatures on Flexural Strength of Macro-Synthetic Fiber Reinforced Concrete: Experimental and Numerical Investigation

Aidarov, Stanislav; Nogales, Alejandro; Reynvart, Igor; Tošić, Nikola; Antequera, Albert de la Fuente

doi:10.3390/ma15031153

Cited by 15 publications

(9 citation statements)

References 57 publications

(50 reference statements)

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“…17 Additional information related to the software, material model and input data required may be found elsewhere. [66][67][68][69] In this context, the simulated post-cracking response fundamentally depends on the constitutive models assumed. Therefore, initially, simulations of 3PBT were carried out to derive those models.…”

Section: Numerical Validation Of the Proposed Methodsmentioning

confidence: 99%

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Influence of fiber orientation on flexural‐based design of steel fiber‐reinforced concrete slabs: Experimental and numerical program

Aidarov,

Nogales,

Tošić

et al. 2024

Structural Concrete

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Steel fiber‐reinforced concrete (SFRC) has proven to be a suitable structural material for constructing elevated flat slabs, and several existing office and residential buildings, in which SFRC was used for these components, highlighted the positive outcomes from both technical and sustainability perspectives. However, research on the influence of fiber orientation on the flexural performance of SFRC slabs is relatively scarce despite the fact that a number of studies revealed that the use of constitutive models derived from three‐point bending tests on notched beams leads to overestimations of the bearing capacity of statically indeterminate slabs. In this context, this study aims at presenting an extensive experimental program that consisted of testing three SFRC slabs (3.0 × 3.0 × 0.1 m3) subjected to point load under a statically indeterminate test configuration. The testing procedure was followed by the extraction of 88 cores in order to analyze both fiber distribution and orientation by means of a non‐destructive inductive method. The results indicate that lower orientation numbers were observed in cylinders drilled from the slabs in comparison with those observed in the 150 × 150 × 600 mm3 notched reference beams tested to characterize the pre‐ and post‐cracking flexural performance of the SFRC produced. Based on these results, a straightforward design‐oriented approach to compute an orientation factor was proposed and considered to develop the constitutive law used to simulate the structural response of SFRC slabs by means of nonlinear finite element model. The numerical simulation results showed a good agreement with the experimental response, this evidencing that the orientation factor may permit to account for the differences caused by geometric and statistical scale‐induced factors between both the beams used for the SFRC flexural properties characterization and slabs produced with the same SFRC.

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Section: Numerical Validation Of the Proposed Methodsmentioning

confidence: 99%

“…Both, software and material models, were proven to be suitable for the nonlinear simulations of column‐supported SFRC flat slabs 17 . Additional information related to the software, material model and input data required may be found elsewhere 66–69 …”

Section: Numerical Validation Of the Proposed Methodsmentioning

confidence: 99%

Influence of fiber orientation on flexural‐based design of steel fiber‐reinforced concrete slabs: Experimental and numerical program

Aidarov,

Nogales,

Tošić

et al. 2024

Structural Concrete

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“…However, RA has some disadvantages compared with natural aggregates, such as lower density and strength and higher water absorption than natural aggregate (NA), making quality control of recycled aggregate concrete (RAC) a challenge. At the same time, fibre reinforced concrete (FRC) is being increasingly used in civil engineering structures, such as tunnels, pavements, and flat slabs, owing to its beneficial effect on crack control, fire resistance, fatigue resistance, and impact resistance (Aidarov et al 2022). However, as time goes by, recycling of FRC becomes more urgent.…”

Section: Introductionmentioning

confidence: 99%

Recycling of Polypropylene Fibre Reinforced Concrete: Use of Recycled Aggregate and Recovered Fibre in New Concrete

Liu,

Tosic,

de la Fuente

2023

16th International Conference on Durability of Building Materials and Components

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The study aims at investigating the feasibility of using recycled aggregate (RA) and recovered fibres (RF) obtained from recycling of polypropylene fibre reinforced concrete (PPFRC) in new concrete production. The mechanical properties were compared between a parent concrete, polypropylene fibre reinforced recycled aggregate concrete (PPRAC), and recovered polypropylene fibre concrete (Re-PPRFC). All concretes were designed to have the same compressive strength and slump. The parent concrete was produced with 9 kg/m 3 of polypropylene fibre. After recycling, the RA and RF were collected and new concretes with RA and RF, PPRAC and PPRFC, respectively, were produced with the same fibre content as the parent concretes. The strain-stress relationship in compression and residual tensile strength were tested. The results obtained for PPFRC, PPRAC and rePPRFC were compared. The results show that the RA and RF obtained by PPFRC recycling can benefit new concrete production.

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“…To solve the aforementioned disadvantages of the concrete, the strengthening method has been proposed to incorporate mixing the concrete with random discrete fibers. For example, carbon, glass, steel, and polypropylene contribute to the addition of fibers to concrete to improve energy absorption and tensile resistance to cracking (Lee et al, 2016;RAS, 2006).Generally, an attractive alternative for conventional steel bar reinforced concrete constructions is fiber reinforced concrete (FRC) (Aidarov et al, 2022). The fiber is used as internal reinforcement in concrete constructions and leads the concrete to have less cracking, so the fibers are used to enhance its tensile and ductile behaviour.…”

mentioning

confidence: 99%

“…Generally, an attractive alternative for conventional steel bar reinforced concrete constructions is fiber reinforced concrete (FRC) (Aidarov et al, 2022). The fiber is used as internal reinforcement in concrete constructions and leads the concrete to have less cracking, so the fibers are used to enhance its tensile and ductile behaviour.…”

mentioning

confidence: 99%

Flexural Behavior of High Strength RC Beams Incorporating Nano-Silica and Macro-Polypropylene Fiber

Mohammed

Saeed

2022

UKH J SCI ENG

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This paper investigates the flexural behavior of high-strength RC beams experimentally to assess the effect of Nano-silica (NS) and Macro-Synthetic High Strength Polypropylene Fiber (MPF). Ordinary Portland cement was partially replaced by the NS and MPF with different proportions to produce four concrete mixtures. Tests were conducted on the full-scale high-strength RC beams, including first crack load, failure load, deflection, concrete strain, steel strain, and mode failure, which were examined and compared. In addition, the tests on the mechanical properties of high-strength concrete mixtures were also conducted at the ages of 28 and 56 days. The test results concluded that the addition of NS and MPF significantly improved the first-cracking and failure loads and decreased deflection at levels of cracking and failure loads. Additionally, an increase in NS content resulted in a minor increase in the ultimate strain related to the failure loads. Furthermore, the mix of 3% NS with 0.5% MPF was found to lead to the highest mechanical characteristics of concrete. The improvements were the concrete compressive strength by 33.6%, split tensile strength by up to 54.1%, and flexural strength by up to 28.3% compared with control specimens.

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Effects of Low Temperatures on Flexural Strength of Macro-Synthetic Fiber Reinforced Concrete: Experimental and Numerical Investigation

Cited by 15 publications

References 57 publications

Influence of fiber orientation on flexural‐based design of steel fiber‐reinforced concrete slabs: Experimental and numerical program

Influence of fiber orientation on flexural‐based design of steel fiber‐reinforced concrete slabs: Experimental and numerical program

Recycling of Polypropylene Fibre Reinforced Concrete: Use of Recycled Aggregate and Recovered Fibre in New Concrete

Flexural Behavior of High Strength RC Beams Incorporating Nano-Silica and Macro-Polypropylene Fiber

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