Investigating the Mechanical Properties and Durability of Metakaolin-Incorporated Mortar by Different Curing Methods

Dong, Yudong; Pei, Lianjun; Fu, Jin-Dong; Yang, Yalong; Liu, Tong; Liang, Huihui; Yang, Heng

doi:10.3390/ma15062035

Cited by 13 publications

(4 citation statements)

References 35 publications

(39 reference statements)

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“…Matrix, owing to its minuscule particle size. Slag and metakaolin proportions are influenced by factors such as density, setting time, CS, toughness, and ranges of Poisson (µ) [10]. One of the tests for fresh qualities is slump flow testing for hardened properties include determining the concrete's split tensile and compressive strengths.…”

Section: Introductionmentioning

confidence: 99%

Mechanical Properties of Quaternary Blended Geopolymer Concrete

Kommala,

Kolli

2024

J. Phys.: Conf. Ser.

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Over the past decade, Geopolymers were considered as a novel promising material for sustainable development in the construction industry. It is a well-known fact that to reduce the usage of OPC concrete, usage of alternative binders is mandatory. Past Literature reveals that Industrial wastes such as Fly ash, GGBS, Metakaolin and Rice husk ash were extensively used in geopolymer concrete in the form of combination of binary, ternary and quaternary blended concretes. However, there is a very little report was reported on binary and Ternary blended geopolymer concrete. The research work on Quaternary blended concrete using Fly ash, GGBS, metakaolin and Wollastonite was not reported so far. Geopolymer concrete is a novel substance involves various chemical compositions and reactions in a binding material. The research work focused upon on the mix design and mechanical characteristics of binary, Ternary and quaternary blended geopolymer concrete. Quaternary blended GPC is made up of four binding components namely Fly Ash, Ground Granulated Blast Furnace Slag, Metakaolin, and Wollastonite. The Binary blended GPC i.e. Fly Ash to GGBS ratio, geopolymer mix was 70:30. The ratios of Fly Ash: GGBS: Metakaolin for the ternary blended mix were 50:30:20& Fly Ash: GGBS: Metakaolin: Wollastonite for the quaternary geopolymer mixtures is 30:30:20:20 respectively. Wollastonite is a calcium metasilicate (CaSiO3) mineral. Sodium, when present in an alkaline solution alongside silicate and hydroxide, triggers the activation of the binding elements. The alkaline promoter (NaOH/Na2SiO3) ratio was set at 2.5, while the precise amount of sodium hydroxide (NaOH) had been maintained at 8M(Molarity). The present experimental investigation demonstrates that mechanical properties of GPC such as compressive strength, flexural strength and split tensile strength for Quaternary blended Geopolymer concrete have outperformed the other two blends i.e. binary and ternary blended GPC due to the Wollastonite based quaternary binder.

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Section: Introductionmentioning

confidence: 99%

Mechanical Properties of Quaternary Blended Geopolymer Concrete

Kommala,

Kolli

2024

J. Phys.: Conf. Ser.

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“…Metakaolin's unique chemical composition allows it to function as a perfect additional cementing component among various nutrients and residues already used in construction such as various powder contents [53]. While employed as a partial substitution for cement, it gives advantages in terms of mechanical strength and tolerance to the intrusion of hostile substances [54]. Tafraoui et al [55] discovered that the improvements in mechanical properties and durability of concrete made with MK are comparable to the advances made with silica fume.…”

Section: Introductionmentioning

confidence: 99%

Utilization of Waste Glass Cullet as Partial Substitutions of Coarse Aggregate to Produce Eco-Friendly Concrete: Role of Metakaolin as Cement Replacement

Hasan,

Shaurdho,

Sobuz

et al. 2023

Sustainability

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The utilization of waste products is becoming a vital aspect of the construction industry to safeguard environmental assets and mitigate pollution, all of which lead to long-term sustainable development. From this perspective, this experimental investigation was carried out to determine the cumulative influence of waste glass cullet and metakaolin (MK) as partial replacements for coarse aggregates and cement in an isolated and combined manner. This research demonstrated the influence of integrating glass aggregate and metakaolin wherein coarse aggregate was substituted by 10%, 15%, 20%, 25%, and 30% glass cullet (by weight), and cement was supplemented with 10% metakaolin. The substitution of waste glass with coarse aggregate significantly declines the compressive strength correspondingly; however, the integration of 10% metakaolin powder enhanced the strength slightly for all specimens up to 25%. On the other hand, for flexural strength, the inclusion of glass waste in concrete reduced the performance, whereas the incorporation of metakaolin boosted the strength but did not achieve greater strength compared to the control mixture. The sustainability analysis revealed that the production cost and eCO2 emission could be reduced by 15% and 7% by incorporating glass cullet and metakaolin in the concrete mix, which satisfied sustainability. Based on the experimental results, the ideal proportion substitution would be 25% glass aggregate with 10% metakaolin, which could satisfactorily be used to generate sustainable concrete.

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“…Replacing part of cement in mortar or concrete with mineral admixtures can reduce cement consumption, thereby reducing carbon dioxide emissions and natural resource consumption [ 4 , 5 ]. At the same time, mineral admixtures can also improve the performance or strength of concrete mixture [ 11 , 14 , 15 , 16 ]. In addition, the accumulation of industrial solid waste such as fly ash will occupy many land resources, and dust will also cause serious air pollution.…”

Section: Introductionmentioning

confidence: 99%

Study on the Mechanical Properties, Wear Resistance and Microstructure of Hybrid Fiber-Reinforced Mortar Containing High Volume of Industrial Solid Waste Mineral Admixture

Jia

Yuan

et al. 2022

Materials

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The use of a high volume of industrial solid waste mineral admixture and hybrid fiber can greatly reduce the amount of cement in mortar or concrete, improve its performance, ensure the service properties of mortar or concrete, and reuse industrial solid waste to reduce the environmental burden, which has significant research significance. In this paper, the mechanical properties, wear resistance and microstructure of hybrid fiber-reinforced mortar (HFRM) with a high content of industrial solid waste mineral admixture were systematically studied under different water/binder ratios. Mineral admixtures include fly ash, silica fume and granulated blast furnace slag (slag). The total content of hybrid glass fiber (GF) and polypropylene fiber (PPF) was 2% by volume fractions, and six different water/binder ratios ranging from 0.27 to 0.62 were used. The following conclusions were drawn: fibers have a significant negative effect on the properties of mortars with a low water/binder ratio (w/b = 0.27) and high content of mineral admixtures. In general, the effect of adding hybrid fiber on improving the wear resistance of mortar is more obvious. The average residual weight of hybrid fiber-reinforced mortar is the highest after the wear resistance test. Comprehensively considering the compressive strength, flexural strength, wear resistance and microstructure of the mortar samples, G8PP2-0.40 is the optimal mix ratio. At this time, the replacement rates of fly ash, silica fume and slag are: 20%, 5% and 30%, the water/binder ratio is 0.40, and the content of GF and PPF is 1.6% and 0.4%, respectively.

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Investigating the Mechanical Properties and Durability of Metakaolin-Incorporated Mortar by Different Curing Methods

Cited by 13 publications

References 35 publications

Mechanical Properties of Quaternary Blended Geopolymer Concrete

Mechanical Properties of Quaternary Blended Geopolymer Concrete

Utilization of Waste Glass Cullet as Partial Substitutions of Coarse Aggregate to Produce Eco-Friendly Concrete: Role of Metakaolin as Cement Replacement

Study on the Mechanical Properties, Wear Resistance and Microstructure of Hybrid Fiber-Reinforced Mortar Containing High Volume of Industrial Solid Waste Mineral Admixture

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