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In several countries, the use of recycled coarse aggregate in construction materials is recommended; however, the use of organic matter is restricted because it can produce significant changes in compressive strength. In terms of reaching a conclusive viewpoint regarding the research topic, secondary data collection analysis has been selected. It is essential to utilize the recycled and by-products wastages to prepare alternative materials as this can be useful in generating a significant amount of fine concrete aggregate. As a result, it reduces the extreme exploration of essential natural resources and meets the requirements of natural concrete aggregates by using the alternative and recycled fine concrete aggregate. Moreover, the alternative materials come with similar properties and physical behaviour as they sustain the durability and compound stability of the concrete aggregate through the use of recycled cement. The disposal of industrial wastes can cause extreme environmental harm that can be reduced via recycled cement. However, it has been noted that the presence of harmful materials can result in issues regarding durability. Thus, it is essential to arrange materials for recycled cement that can be effective for construction activities. In order to maintain environmental sustainability and reduce environmental hazards, it is important to utilize the wastages for generating alternative concrete aggregates such as crushed rocks. Thus, this paper reviews the environmental effects of concrete waste pollutants and its sustainable reutilization to promote a cleaner environment and offer benefits to the construction industries with a positive effect.
Wydawca
Rocznik
Tom
Strony
233--242
Opis fizyczny
Bibliogr. 45 poz., rys., tab.
Twórcy
autor
- Department of Civil Engineering, Sona College of Technology, Salem 636005, India
autor
- Department of Civil Engineering, Sona College of Technology, Salem 636005, India
Bibliografia
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- 5. Andrade G.P., Castro Polisseni G., Pepe M., Toledo Filho R.D. 2020. Design of structural concrete mixtures containing fine recycled concrete aggregate using packing model. Construction and Building Materials, 252, 119091.
- 6. Awoyera P.O., Babalola O.E., Olalusi O.B., Tran M.T., Le D.H., Ovallos-Gazabon, D., Viloria, A. 2020. Mechanical and durability properties of recycled aggregate concrete with ternary binder system and optimized mix proportion. Journal of Materials Research and Technology, 9(3), 6521–6532.
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- 10.Evangelista L., de Brito J. 2007. Mechanical behaviour of concrete made with fine recycled concrete aggregates. Cement and concrete composites, 29(5), 397–401.
- 11. Fan C.C., Huang R., Hwang H., Chao S.J. 2015. The effects of different fine recycled concrete aggregates on the properties of mortar. Materials, 8(5), 2658–2672.
- 12. Gedela S.K., Subhani S.M., Bahurudeen A. 2021. Cleaner production of concrete by using industrial by-products as fine aggregate: A sustainable solution to excessive river sand mining. Journal of Building Engineering, 42, 102415.
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- 23. Leite M.B., Santana V.M. 2019. Evaluation of an experimental mix proportion study and production of concrete using fine recycled aggregate. Journal of Building Engineering, 21, 243–253.
- 24. Li L., Zhan B. J., Lu J., Poon C. S. 2019. Systematic evaluation of the effect of replacing river sand by different particle size ranges of fine recycled concrete aggregates in cement mortars. Construction and Building Materials, 209, 147–155.
- 25. Li Z., Liu J., Xiao J.Z., Zhong P., Wang, J. 2020. Drying shrinkage of mortar manufactured with recycled fine aggregate at vary initial saturation degree. Construction and Building Materials, 264, 120621.
- 26. Mistry, V.K., Varia, D.J. 2020. Green concrete by replacing coarse aggregate with cupola slag for environmental protection. Paper presented at conference on Renewable Energy and Climate Change, Singapore, 142–149.
- 27. Nasiri B.A., Nematzadeh M. 2017. The effect of elevated temperatures on the mechanical properties of concrete with fine recycled refractory brick aggregate and aluminate cement. Construction and Building Materials, 147, 865–875.
- 28. Nedeljković M., Visser J., Šavija B., Valcke, S., Schlangen, E. 2021. Use of fine recycled concreto aggregates in concrete: A critical review. Journal of Building Engineering, 38, 102196.
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- 30. Nuaklong P., Wongsa A., Boonserm K., Ngohpok C., Jongvivatsakul P., Sata V., Sukontasukkul P., Chindaprasirt P. 2021. Enhancement of mechanical properties of fly ash geopolymer containing fine recycled concrete aggregate with micro carbon fiber. Journal of Building Engineering, 41, 102403.
- 31. Oluwasola E.A., Afolayan A., Ameen I.O., Adeoye, E.O. 2020. Effect of Curing Methods on the Compressive Strength of Palm Kernel Shell Aggregate Concrete. Lautech Journal of Civil and Environmental Studies, 5, 11–17.
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- 33. Pareek K., Saha S., Gupta N., Saha, P. 2019. Effect of recycled aggregate on mechanical and durability properties of concrete. International Journal of Structural and Civil Engineering Research, 8(2), 119–125.
- 34. Rajput S.P. 2018. An experimental study on crushed stone dusts as fine aggregate in cement concrete. Materials Today: Proceedings, 5(9), 17540–17547.
- 35.Rhishi, R.K., Vasudev, R. 2022. A review on the effects of artificial light weight aggregate in concrete. Sustainability, Agri, Food and Environmental Research, 10(1), 1–11.
- 36. Saba, M., Asaad, J. J. 2021. Effect of recycled fine aggregates on performance of geopolymer masonry mortars. Construction and Building Materials, 279, 122461.
- 37. Saedi A., Zanjani A., Darban A.K. 2020. A review on different methods of activating tailings to improve their cementitious property as cemented paste and reusability. Journal of Environmental Management, 270, 110881.
- 38. Saha A.K., Sarker P.K. 2017. Sustainable use of ferronickel slag fine aggregate and fly ash in structural concrete: Mechanical properties and leaching study. Journal of cleaner production, 162, 438–448.
- 39. Salahuddin H., Qureshi L. A., Nawaz A., Raza S.S. 2020. Effect of recycled fine aggregates on performance of reactive powder concrete. Construction and Building Materials, 243, 118223.
- 40. Schoon J., De Buysser K., Van Driessche I., De Belie N. 2015. Fines extracted from recycled concrete as alternative raw material for Portland cement clinker production. Cement and Concrete Composites, 58, 70–80.
- 41. Silva Neto G.A.D., Leite M.B. 2018. Study of the influence of the mortar fine recycled aggregate ratio and the mixing sequence on the behaviour of new mortars. Ambiente Construído, 18(2), 53–69.
- 42. Sim J., Park C. 2021. Compressive strength and resistance to chloride ion penetration and carbonation of recycled aggregate concrete with varying amount of fly ash and fine recycled aggregate. Waste management, 31(11), 2352–2360.
- 43. Wang Y., Liu F., Xu L., Zhao H. 2019. Effect of elevated temperatures and cooling methods on strength of concrete made with coarse and fine recycled concrete aggregates. Construction and Building Materials, 210, 540–547.
- 44. Zachariah J.P., Sarkar P.P., Debnath B., Pal M. 2018. Effect of polypropylene fibres on bituminous concrete with brick as aggregate. Construction and Building Materials, 168, 867–876.
- 45. Zhang H., Wang Y., Lehman D. E., Geng Y., Kuder K. 2020. Time-dependent drying shrinkage model for concrete with coarse and fine recycled aggregate. Cement and concrete composites, 105, 103426.
Uwagi
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-bf4df4e3-a744-4559-b886-bc698cede725