Experimental Study on Self Compacting Self Curing Concrete Using Copper Slag as Partial Replacement of Fine Aggregate

Paul, Anisha Mariya; George, Elba Helen

doi:10.1007/978-3-030-26365-2_10

Cited by 5 publications

(2 citation statements)

References 7 publications

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“…For example, the coarse aggregate was replaced by lightweight aggregate that produced from various sources such as palm oil [19], expanded clay [20] and lava [2,21]. Fine aggregate was replaced by Tyre Rubber [22], Copper Slag [23] and Mica [24]. One the other hand, the cement was replaced by GGBS [14], CKD [25], Fly ash [26], rice husk ash [27] and bottom ash [28].…”

Section: Introductionmentioning

confidence: 99%

Properties of eco-friendly cement mortar contained recycled materials from different sources

Nasr

Shubbar

Abed

et al. 2020

Journal of Building Engineering

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Section: Introductionmentioning

confidence: 99%

Properties of eco-friendly cement mortar contained recycled materials from different sources

Nasr

Shubbar

Abed

et al. 2020

Journal of Building Engineering

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“…Their study revealed combined potential to enhance strength and durability. By systematically investigating their interaction, the research showcased the promise of optimizing SCC's microstructure and mechanics through this partnership, offering a dynamic enhancement strategy for SCC [22]. The economic feasibility of fly ash incorporation in selfcompacting concrete (SCC).…”

Section: Introductionmentioning

confidence: 99%

Optimizing flow, strength, and durability in high-strength self-compacting and self-curing concrete utilizing lightweight aggregates

Kadhar,

Gopal,

Sivakumar

et al. 2024

Matéria (Rio J.)

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This comprehensive study undertaken to investigate the properties and performance of M60 grade selfcompacting and self-curing concrete mix designs. The research involved an in-depth analysis of various concrete compositions labeled as M1 to M16, each with specific aggregate combinations and percentages. The primary focus was on assessing critical properties such as flow-ability, mechanical, durability and micro structural properties. The mix labeled as M6, featuring a balanced incorporation of fine aggregate alternatives (FAA) and natural coarse aggregates (NCA), exhibited noteworthy behavior in terms of the evaluated properties. This indicated the potential advantages of judiciously combining different types of aggregates to achieve desired concrete characteristics. The research underscored the critical role of aggregate selection and substitution in determining the overall durability, strength, and structural performance of M60 grade concrete. These findings contribute to an improved understanding of optimizing concrete mix designs for achieving enhanced mechanical properties, micro structural and long-term structural sustainability. The mix M12 is more superior compared to all the mix in the form of fresh concrete properties, mechanical properties and durability properties of concrete. This study's outcomes have implications for the construction industry, offering valuable insights into formulating concrete blends tailored for specific structural requirements and desired performance outcomes.

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From hazardous waste to fertilizer: Recovery of high-value metals from smelter slags

et al. 2022

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Experimental Study on Self Compacting Self Curing Concrete Using Copper Slag as Partial Replacement of Fine Aggregate

Cited by 5 publications

References 7 publications

Properties of eco-friendly cement mortar contained recycled materials from different sources

Properties of eco-friendly cement mortar contained recycled materials from different sources

Optimizing flow, strength, and durability in high-strength self-compacting and self-curing concrete utilizing lightweight aggregates

From hazardous waste to fertilizer: Recovery of high-value metals from smelter slags

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