English
Русский 27-34 p.
During the implementation of the program to restore the housing stock of the Chechen Republic, as well as during the planned demolition of dilapidated housing, significant volumes of technogenic raw materials were generated, in particular, large volumes of brick and concrete scrap. Enterprises for the production of building materials and products also produce significant volumes of production defects, which accumulate over the years at landfills. Ceramic broken brick and broken brick dropouts are used to fill the roadbed, and the main part still goes to the dump and landfill, which is also an environmental problem. One of the promising ways to use dropouts and broken brick itself is to use them as secondary aggregates in concrete and mortars. This article discusses the issues of improving the quality of ceramic concrete mixtures, choosing the optimal composition and technology for mixing concrete mixtures using dust fractions of dropouts for crushing ceramic brick bricks.
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3. Sobhan MA, Zakaria M (2001) Experimental behaviour of BM mixes with brick Aggregates. J Civ Eng Inst Eng Bangladesh 29:115–123
4. Debieb F, Kenai S (2008) The use of coarse and fine crushed bricks as aggregate in concrete. Constr Build Mater 22:886–893. (https://doi.org/10.1016/j.conbuildmat.2006. 12.013)
5. Rasel HM, Sobhan MA, Rahman MN (2011) Performance evaluation of brick chips as coarse aggregate. SAMRIDDHI-A J Phys Sci Eng Technol 2:37–46.
6. Bazhenov Yu.M., Murtazaev S-A.Yu., Saydumov M.S. Construction composites based on concrete scrap and stone crushing waste: scientific edition. Grozny: FSUE “Publishing and Printing Complex “Grozny Worker”, 2014. 334 p. (rus.)
7. Bazhenov Yu. M., Bataev D.K-S., Mazhiev Kh.N., et al. Fine-grained concrete from secondary raw materials for the repair and restoration of damaged buildings and structures: scientific publication. Grozny: IE “Sultanbegova H.S.”, 2011. 342 p. (rus.)
8. Murtazaev S-A.Yu., Bataev D.K-S., Ismailova Z.Kh., et al. Fine-grained concrete based on fillers from secondary raw materials: scientific edition. Moscow: “Komtechprint”, 2009. 142 p. (rus.)
9. Usov B.A. Physico-chemical processes of building materials science in the technology of concrete and reinforced concrete: textbook. manual for students in the specialty 270106 “Production of building materials, products and structures”. Moscow: MRSU Publishing house, 2009. 326 p. (rus.)
10. Bazhenov Yu.M., Bataev D.K-S., Murtazaev S-A.Yu. Energy- and resource-saving materials and technologies for the repair and restoration of buildings and structures: scientific edition. Moscow: Publishing House “Komtechprint”, 2006. 235 p. (rus.)
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12. http://dstu.ru/fileadmin/Diss._KHadzhieva_M.R._na_sait.pdf
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14. Dobshits L.M., Kononova O.V., Anisimov S.N. Kinetics of strength set of cement stone with modifying additives. Cement and its application. 2011. 4. P. 104 – 107. (rus.)
15. Bazhenov Yu.M. Concrete of the XXI century. Resource – and energy-saving technologies of building materials, products and structures: col. of scient. articles of Internat. conf. Belgorod, 1995. P. 3 – 5. (rus.)
16. Dolgopolov N.N., Fedner L.A., Sukhanov M.A. Some questions of the development of construction materials technology. 1994. 1. P. 5 – 6. (rus.)
17. Mehta P K 2004 Proceedings of the International Workshop on Sustainable Development & Concrete Technology, (Beijing).
18. Marcus M.I., Deak G.y, Dumitru F.D., Moncea M.A., Panait A.M., Maria C. 2019, IOP Conf. Ser.: Mater. Sci. Eng. 572 012076
19. Arribas I., Vegas I., San-José J.T. and Manso J.M. 2014 Mater. Des. 63 168-176;
20. Aliabdo A.A., Abd Elmoaty M.A.E. and Aboshama A.Y. 2016 Constr Build Mater 124 866.
21. Quina M.J. and Pinheiro C.T., 2020 Appl. Sci. 10 2317.
22. Moncea M., Dumitru F., Baraitaru A., Boboc M., Deák G., Razak R. Assessing the Recovery Opportunities of Different Types of Wastes by their Embedment in Inorganic Binders. 2nd International Conference on Green Environmental Engineering and Technology, IOP Conf. Series: Earth and Environmental Science 616 (2020) 012044 (doi:10.1088/1755-1315/616/1/012044)
23. Gomes M.I., Faria P., Gonçalves T.D. Earth-based mortars for repair and protection of rammed earth walls stabilization with mineral binders and fibers, J. Clean. Prod. 172 (2018) 2401–2414, https://doi.org/10.1016/j.jclepro.2017.11.170
24. Melià P., Ruggieri G., Sabbadini S., Dotelli G. Environmental impacts of natural and conventional building materials: a case study on earth plasters, J. Clean. Prod. 80 (2014) 179–186, https://doi.org/10.1016/j.jclepro.2014.05.073
25. Cagnon H., Aubert J.E., Coutand M., Magniont C. Hygrothermal properties of earth bricks, Energy Build. 80 (2014) 208–217. https://doi.org/10.1016/j.enbuild.2014. 05.024
Murtazaev S-A.Yu., Uspanova A.S., Khadzhiev M.R., Khadisov V.Kh. Analysis of the influence of industrial waste in the form of ceramic chips crushing dropouts on the main properties of cement composites. Construction Materials and Products. 2021. 4 (1). P. 27 – 34. https://doi.org/10.34031/2618-7183-2021-4-1-27-34