A Study on the Mechanical Properties of Green Concrete

Williams, Kanmalai; Balamuralikrishnan, R.; Joe, Adams; Prince, Shalin

doi:10.28991/cej-2022-08-05-012

Cited by 9 publications

(3 citation statements)

References 24 publications

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“…Al-Omari & Al-Mashhadani [3] discovered that increasing the amount of stone powder in concrete increased the compressive strength of the material up to a certain point. The inclusion of stone powder was also identified in the investigation by Islam & Hossain [4].…”

Section: Introductionmentioning

confidence: 94%

“…Furthermore, multiple studies have indicated that the inclusion of stone powder can increase the flexural and compressive strength of concrete. From an economic standpoint, incorporating stone powder into concrete can help reduce the cost of cement mixtures [3,4]. However, it is important to note that the literature also highlights certain drawbacks of using stone powder, such as potential variations in quality, which can impact workability, and a potential decrease in abrasion resistance if high fractions are employed [5].…”

Section: Introductionmentioning

confidence: 99%

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Recycling of Basalt and Limestone Cutting Dust in Concrete Mix Design

Awad,

Shaqadan,

Al-Adwan

et al. 2023

Civ Eng J

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Objectives: The goal is to integrate stone cutting waste into the concrete manufacturing industry to reduce environmental degradation. Methods/Analysis: Two types of stone cutting waste (Basalt and limestone) were separately collected from local facilities. An experimental program was conducted to prepare concrete mixes with 10%, 20%, 30%, and 40% replacement of sand by the two types of stone powder. Physical and chemical quality testing was carried out on the water, aggregates, and cement used in the concrete mix. The experiment compared a standard concrete mix (0% replacement) consisting of 6 cylinders and 6 cubes with a mix of 24 cylinders and 24 cubes after 7 days and 28 days. Results: Compression, tension, and stress tests were performed on the produced specimens. Regarding basalt replacement, a 10% replacement showed a higher impact on compressive strength and tension. For limestone, the 10% and 40% replacement fractions exhibited an insignificant reduction in compressive strength, indicating that a 40% replacement of sand with limestone dust is practical for most applications. Replacing sand with stone cutting waste in concrete can bring several benefits to the environment and enhance project feasibility. Even a small fraction of replacement can improve concrete properties. Novelty:Protect natural sand mining causes damage to ecosystems, leading to erosion and loss of biodiversity. Doi: 10.28991/CEJ-2023-09-05-010 Full Text: PDF

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Section: Introductionmentioning

confidence: 94%

Section: Introductionmentioning

confidence: 99%

Recycling of Basalt and Limestone Cutting Dust in Concrete Mix Design

Awad,

Shaqadan,

Al-Adwan

et al. 2023

Civ Eng J

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“…Without causing any negative effects, the catalytic cracking catalyst may be used to replace 10% of the sand or 15% to 20% of the cement content [18,19]. To strengthen the strength of structural elements, ferrocement was adhered to their surfaces [ 20,21]. It reduces concrete permeability and prevents cracking brought on by drying shrinkage and thermal expansion [22].…”

Section: Spent Catalystmentioning

confidence: 99%

Seismic Upgradation of RC Beams Strengthened with Externally Bonded Spent Catalyst Based Ferrocement Laminates

Balamuralikrishnan,

Al-Mawaali,

Al-Yaarubi

et al. 2023

HighTech. Innov. J.

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Globally, since there are more systems of civil infrastructure, there are also more degraded buildings and structures. If upgrading or strengthening is a practical option, complete replacement is likely to be an escalating financial burden and may be a waste of natural resources. It is necessary to repair or strengthen a number of reinforced concrete buildings and structures in order to boost their load-bearing capabilities or improve their ductility under seismic stress. Additionally, due to changes in service circumstances, a structure might need to be modified to reduce deflections or manage cracking. Strengthening may be preferable to limiting usage, capping applied loads, and regularly inspecting the structure rather than removing the existing structure or part and building a new one. This study aims to examine the flexural, shear, and combined effect of flexural and shear behavior of reinforced concrete (RC) beams strengthened with externally bonded spent catalyst-based ferrocement laminates and compare them to the control beams (unstrengthened) under two-point loading conditions. This study involves researching laminates with various spent catalyst doses, such as 3, 6, 9, and 12%, in an effort to determine the best amounts that will improve the structural performance of ferrocement laminates. Twelve spent catalyst-based ferrocement laminates measuring 500(L) × 125(B) × 20 mm (thickness) with 3% volume fraction of meshes each were cast and tested in the lab as part of the preliminary investigation. For repeatability, three laminates per case were employed. Eight numbers of under-reinforced RC beams measuring 75(L) × 100(B) × 150(D) mm were cast for the main study; six numbers were strengthened with optimized spent catalyst-based ferrocement laminates bonded with flexible epoxy systems at the tension zone, shear zone, and combination of tension and shear zone. Two of the beams were cast as control specimens. The beams were then evaluated using a Universal Testing Machine (UTM) with a 1000 kN capacity under two-point loading conditions. As a result, the strength, yield load, ultimate load, stiffness, ductility, and related failure modes of all tested beams' flexural and shear performances were examined. According to a preliminary analysis of laminates made of spent catalyst, the dosage of 9% provides good flexural strength in comparison to other doses. In comparison to the strengthened beam, the control beam's initial cracks appeared earlier. In comparison to the control beam, the strengthened beam has an increase in load-carrying capacity of 18% for flexure, 16% for shear, and 30% for the combined impact of flexure and shear. In comparison to the control beam, the deflection of the strengthened beam was decreased by close to 20 to 40% for flexure, 10 to 30% for shear, and 15 to 20% for the combined effects of flexure and shear at the same load level. In relation to control beams, the ductility also improved up to 30% for flexure, 25% for shear, and 25% for the combined impact of flexure and shear. Similar to this, the retrofitted beam is stiffer than the control beam by approximately 40% for flexure, 48% for shear, and 30% for the combined effect of flexure and shear. Theoretical formulation by section analysis is also derived and it gives close agreement with control and strengthened beams. The flexural and shear strengthening of the RC beam retrofitting system is effectively increased by using spent catalyst-based ferrocement laminates. No beam showed signs of premature and brittle failure. According to the test findings, it can be said that spent catalyst-based ferrocement reinforced beams perform better in every way than control beams. Doi: 10.28991/HIJ-2023-04-01-013 Full Text: PDF

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