Flexural behaviour of reinforced concrete beams containing waste plastic fibers

Al‐Hadithi, Abdulkader Ismail; Abdulrahman, Mazin B.; Al-Rawi, M. I.

doi:10.1088/1757-899x/737/1/012173

Cited by 15 publications

(9 citation statements)

References 10 publications

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“…The performance of the developed models was then compared with the performance of the experimentally determined amounts. The statistical value of input variables as well as output variables for training (75%) and testing (25%) data phases are presented in Table 3 2 …”

Section: Methodsmentioning

confidence: 99%

Retracted: Predicting the compressive strength of modified recycled aggregate concrete

Yang

Feng

Esmaeili‐Falak

2022

Structural Concrete

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Reuse and recycling of construction wastes effectively prevent further destruction of the environment and nature due to the construction industry. One of the conventional methods is the reapplication of recycled aggregates (RAs) in concrete mix design and construction. Compressive strength (CS) is a considerable representation of the mechanical properties of recycled aggregate concrete (RAC). The present study is divided into two parts of experimental and predicting. In the laboratory studies phase, RA was used with 100% replacement. Due to the proven defects in RAC, glass fibers and silica fume (variables) have been used to compensate for these defects. Different mixing designs were used to construct concrete samples, and then the CS of each specimen was measured in the laboratory. Afterward, these data were used as training and testing in various conventional, ensembled and hybrid models as the tree-based learning algorithms, rules, Lazy-learning Algorithms, Functions, and Meta classifiers. Considering the applied performance statistical criteria (R 2 , root mean squared error, mean absolute error, and mean absolute percentage error), all models have provided excellent and acceptable results, which the precision of the multilayer perceptron single model and additive regression-random Forest hybrid model have the best agreement with measured values of CS of RAC.

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Section: Methodsmentioning

confidence: 99%

Retracted: Predicting the compressive strength of modified recycled aggregate concrete

Yang

Feng

Esmaeili‐Falak

2022

Structural Concrete

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“…In addition, Borg et al (2016) [10] noted a 0.5% to 8.5% strength reduction that on the addition of PET fibres in concrete due to the low elastic modulus of plastic fibres resulting in poor composite action [54], findings which have been supported by other researchers [55]. However, some studies show a slight improvement of compressive strength at 0.5% [44,50] and 1% [56] fibre dosage. It is worthwhile to note that in most of the studies that report an increase in compressive strength, short, smooth fibres were used, and hence fair compaction was achieved.…”

Section: Figure 10 Compressive Strength Results For the Different Sur...mentioning

confidence: 84%

“…The lack of composite action between the fibres and concrete ingredients creates lines of weakness and introduces voids in the matrix, making the concrete porous and thus lowering its compressive strength. Uneven distribution of fibres is experienced with longer fibres, increasing the micro-crack envelopes and hence reducing the loading required to propagate cracks until failure [13,56]. This, coupled with the incomplete compaction as the fibre length increases, leads to a subsequent reduction in the compressive strength.…”

Section: Figure 16 Compressive Strength Values For Varying Fibre Lengthsmentioning

confidence: 99%

“…Despite the good bonding of sand-coated fibres, increasing their content makes the concrete matrix more porous and their low elastic modulus offers no resistance to the compressive forces compared to say steel fibres. Most of the studies that report an improvement in the compressive strength of concrete on the inclusion of fibres use consistently short fibres (within a range of 15-50 mm) [13,56,62] and this improvement only occurs at low fibre dosages.…”

Section: Compressive Strengthmentioning

confidence: 99%

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Properties of Concrete Produced using Surface Modified Polyethylene Terephthalate Fibres

2022

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Conventional techniques of improving the bond properties of virgin Polyethylene Terephthalate Fibres reduce the mechanical strength of the fibres, are labour intensive, and present environmental hazards in the case of chemical treatment. This study introduces a new way of improving the bond properties of fibres obtained from waste Polyethylene Terephthalate bottles by coating the surface of the fibres with a thin layer of sand to counteract the above-mentioned shortcomings. Their performance was compared to that of embossed, serrated, and straight fibres and a control mix without fibres. Workability, compressive strength, tensile and flexural strength were used to assess this performance. Constant fibre length, width, and content were maintained for this exercise. Compared to the other fibres, sand-coated fibres gave the highest increment in tensile and flexural strength of 9.49% and 11.61% compared to the control mix, even though concrete’s workability and compressive strength were decreased. Furthermore, the optimization of the fibre length and content for the sand-coated fibres was carried out. The 75 mm long fibres showed the highest improvement in tensile strength of 13.76% and flexural strength of 12.49% compared to other fibre lengths. The optimum percentage of fibres was 1.25% with a 15.49% and 17.26% increment in tensile and flexural strengths, respectively. Doi: 10.28991/CEJ-2022-08-06-03 Full Text: PDF

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“…In order to produce WRPF, post-consumer plastics are processed and washed before being sliced manually through a paper shredder or a compact disk (CD) cutter device. The bottom and neck of the plastic bottles are removed for other uses [16,17,[68][69][70]. Other scientists have used long plastic chips made of machined steel waste pieces in commercial vehicle plants [71].…”

Section: Types Of Waste Fibers Used In Cement-based Compositesmentioning

confidence: 99%

A Comprehensive Review on the Utilization of Recycled Waste Fibers in Cement-Based Composites

et al. 2021

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Ecological problems such as natural resource depletion and massive quantities of waste for disposal are now guiding progressive civilization towards sustainable construction. The reduction of natural resources and the discarding of debris into open landfills are the two main environmental concerns. As a result, managing these solid wastes is a major challenge worldwide. In comparison to disposal, insufficient landfills, ecological degradation and the economic load on the relevant agencies, recycling and reusing waste materials have a considerable influence. Waste fiber has been studied for use as a cement-based composite (CBC) ingredient. Recycling waste fibers not only makes the cement composite more cost-effective and long-lasting but also helps to reduce pollution. Plastics, carpets and steels are among the various types of waste fibers reviewed in this study for their applications in cement-based materials. The mechanical properties of CBCs with different kinds of recycled-waste fibers were explored, including their compressive, flexural and splitting tensile strength and durability properties. The use of recycled fibers in the construction industry can help to ensure sustainability from environmental, economic and social standpoints. As a result, additional scientific research is needed, as well as guidance for more researchers and experts in the construction sector to examine the unknown sustainability paths. The barriers to the effective implementation of waste fiber recycling techniques in the construction sector were reviewed, and various solutions were proposed to stimulate and ensure their use in CBCs. It was concluded that CBCs containing recycled fibers provide a long-term and cost-effective alternative for dealing with waste materials.

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Flexural behaviour of reinforced concrete beams containing waste plastic fibers

Cited by 15 publications

References 10 publications

Retracted: Predicting the compressive strength of modified recycled aggregate concrete

Retracted: Predicting the compressive strength of modified recycled aggregate concrete

Properties of Concrete Produced using Surface Modified Polyethylene Terephthalate Fibres

A Comprehensive Review on the Utilization of Recycled Waste Fibers in Cement-Based Composites

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