A Review on Performance of Pervious Concrete Using Waste Materials

Ghosh, Sukamal Kanta; Chaudhury, Ananya; Datta, Rohan; Bera, Dillip Kumar; Student, M. Tech

doi:10.15623/ijret.2015.0425017

Cited by 5 publications

(1 citation statement)

References 17 publications

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“…Due to its less strength, it is not recommended to be used for heavy traffic highways. So, a lot of research is being done to identify the major factors affecting the strength and to improve the structural characteristics without affecting the permeability of the concrete [8].…”

Section: Introductionmentioning

confidence: 99%

WITHDRAWN: Assessment of Strength and Permeability Variation in Pervious Concrete by using Industrial Waste as a Partial Replacement for Cement

kumar

2023

Preprint

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In this study, two issues related to the pervious concrete are addressed, and a proper solution is drawn. The first issue is related to strength and the second one is related to permeability. We have used some of the available industrial waste like fly ash, silica fume, and furnace slag in replacement of cement at 20%, 35%, and 50%. The study is conducted to check whether this waste materials replacement can increase the strength and permeability of pervious concrete. Results revealed that fly ash replacement at 35% gave the best result than no cement replacement in both strength and permeability

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Section: Introductionmentioning

confidence: 99%

WITHDRAWN: Assessment of Strength and Permeability Variation in Pervious Concrete by using Industrial Waste as a Partial Replacement for Cement

kumar

2023

Preprint

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Optimizing Porous Concrete Using Granite Stone-Crushing Waste: Composition, Strength, and Density Analysis

Dvorkin,

Bordiuzhenko,

Tracz

et al. 2024

Applied Sciences

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This study examines the utilization of granite stone-crushing waste in the production of porous concrete, with a particular emphasis on the influence of aggregate composition and cement paste layer thickness on the material’s strength and density. Two types of aggregates were employed in this study: granite crushing screenings and granite crushed stone. The impact of aggregate grain size on the properties of porous concrete properties was investigated, and it was found that the use of granite screenings (2.5–5 mm) resulted in superior concrete characteristics compared to granite crushed stone (5–10 mm). This study puts forward a method for optimizing the composition of porous concrete to achieve an optimal balance of compressive strength and density. A method for the design of porous concrete was proposed, incorporating experimental results and the dependencies of strength on the water/cement ratio (W/C). Equations were developed to predict concrete strength based on W/C and cement paste layer thicknesses (CPLTs). The method provides preliminary mix proportions, which should be validated and adjusted for the final design. The findings demonstrate the potential for utilizing stone-crushing waste to produce environmentally sustainable and high-quality porous concrete.

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Compressive and Flexural Strength of Recycled Reactive Powder Concrete Containing Finely Dispersed Local Wastes

Asteray¹,

Oyawa²,

Shitote³

2018

OJCE

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The main objective of this experimental study is to investigate the behavior of Recycled Reactive Powder Concrete (RRPC) developed from finely dispersed local waste raw materials. In this study, RRPC was developed by utilizing local wastes (finely dispersed waste glass powder, waste fly ash and waste ceramic powder) together with Portland cement, fine sand, admixture, steel fibers and water through full replacement of silica fume as well as quartz powder for sustainable construction practice. In this study, all raw materials for making RRPC were analyzed for X-Ray Fluorescence analysis. For sustainability of local construction works, this study employed standard curing method at ambient temperatures instead of steam curing at higher temperatures. Moreover, hand mixing was used throughout the study. To evaluate the structural performances of the developed RRPC mixes, compressive and flexural strengths of RRPC were investigated experimentally and compared with the control mix. The experimental results indicated that replacing the silica fume fully by finely dispersed local waste glass powder (GP) and fly ash (FA) is a promising approach for local structural construction applications. Accordingly, a mean compressive strength of 62.9 MPa and flexural strength of 8.8 MPa were developed using 50% GP-50% FA at 28 th days standard curing. In this study, 17.56% larger compressive strength and 30.6% flexural strength improvements were observed as compared to the control mix.

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A Review on Performance of Pervious Concrete Using Waste Materials

Cited by 5 publications

References 17 publications

WITHDRAWN: Assessment of Strength and Permeability Variation in Pervious Concrete by using Industrial Waste as a Partial Replacement for Cement

WITHDRAWN: Assessment of Strength and Permeability Variation in Pervious Concrete by using Industrial Waste as a Partial Replacement for Cement

Optimizing Porous Concrete Using Granite Stone-Crushing Waste: Composition, Strength, and Density Analysis

Compressive and Flexural Strength of Recycled Reactive Powder Concrete Containing Finely Dispersed Local Wastes

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