S.-A.Yu. MURTAZAEV1,3, Doctor of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.);
D.A. MEZHIDOV1, Postgraduate Student (This email address is being protected from spambots. You need JavaScript enabled to view it.)
1 Grozny State Oil Technical University named after Academician M.D. Millionshtchikov (100, Isayev Avenue, Grozny, 364051, Chechen Republic, Russian Federation)
2 Academy of Sciences of the Chechen Republic (34, Staropromyslovskoe Shosse, Grozny, 364043, Russian Federation)
3 Complex Research Institute named after Kh.I. Ibragimov, Russian Academy of Sciences (21, Staropromyslovskoe Shosse, Grozny, 364051, Russian Federation)
2. Tudor C., Sova R. Benchmarking GHG emissions: forecasting models for global climate policy. Electronics. 2021. Iss. 10 (24). 3149. DOI: https://doi.org/ 10.3390/electronics10243149
3. Cai B., Wang J., He J., Geng Y. Evaluating CO2 emission performance in China’s cement industry: An enterprise perspective. Applied Energy. 2016. Vol. 166, pp. 191–200. DOI: 10.1016/j.apenergy.2015.11.006
4. Dobrohotova M.V., Matushanskij A.V. Applying the best available techniques concept for the technological transformation of industry under the energy transition conditions. Economica ystoychivogo razvitiya. 2022. No. 2 (50), pp. 63–68. (In Russian).
5. Bashmakov I.A., Skobelev D.O., Borisov K.B., Guseva T.V. Benchmarking Systems for Greenhouse Gases Specific Emissions in Steel Industry. Chernaya metallurgiya. Byulleten’ nauchno-tekhnicheskoi i ekonomicheskoi informatsii. 2021. Vol. 77. Iss. 9, pp. 1071–1086. (In Russian). DOI: https://doi.org/ 10.32339/0135-5910-2021-9-1071-1086
6. Bashmakov I.A., Potapova E.N., Borisov K.B., Lebedev O.V., Guseva T.V. Cement sector decarbonization and development of environmental and energy management systems. Stroitel’nye Materialy [Construction Materials]. 2023. No. 9, pp. 4–12. (In Russian). DOI: https://doi.org/10.31659/0585-430X-2023-817-9-4-12
7. Shiryaev M.V., Yashin S.N., Borisov S.A., Zhogin A.O. Carbon polygons as an element of the formation of a “green economy” in the Russian Federation. Razvitiye i bezopasnost’. 2021. No. 4 (12), pp. 95–104. (In Russian).
8. Lesovik V.S., Fomina E.V. On the problem of designing building composites to protect the human environment. In the collection: Fundamental, exploratory and applied research of the RAASN on scientific support for the development of architecture, urban planning and the construction industry of the Russian Federation in 2021. Moscow. 2022, pp. 177–185. (In Russian).
9. Saidumov M.S., Uspanova A.S., Aliev S.A. Ecological and materials science problems of using technogenic waste in post-crisis areas. In the collection: Science of the XXI century. Problems of academic mobility of a researcher and research methodology. Materials of the II International Scientific and Practical Conference. Under the general editorship of Z.A. Demchenko. 2013, pp. 440–443. (In Russian).
10. Alaskhanov A.Kh., Taimashanov Kh.E., Saidumov M.S., Murtazaeva T.S.A. Modern approaches to the development of multicomponent binders using technogenic raw materials. Vestnik of the GSOTU. Technical science. 2022. Vol. 18. No. 1 (27), pp. 63–70. (In Russian).
11. Lesovik V.S., Fomina E.V., Ayzenshtadt A.M. Some aspects of technogenic metasomatosis in construc-tion material science. Stroitel’nye Materialy [Construction Materials]. 2019. No. 1–2, pp. 100–106. (In Russian). DOI: https://doi.org/10.31659/0585-430X-2019-767-1-2-100-106
12. Travush V.I., Kuzevanov D.V., Kaprielov S.S., Volkov Yu.S. Concrete as an ecological factor in reducing the “carbon footprint” in the living environment. Beton i Zhelezobeton [Concrete and Reinforced Concrete]. 2022. No. 3 (611), pp. 10–14. (In Russian). DOI: https://doi.org/10.31659/0005-9889-2022-611-3-10-14
13. Tokareva S.A., Kabanova M.K. Utilization of large-tonnage waste. Processing, neutralization and obtaining useful products. Stroitel’nye Materialy [Construction Materials]. 2022. No. 5, pp. 25–29. (In Russian). DOI: https://doi.org/10.31659/0585-430X-2022-802-5-25-29
14. Murtazaev S.-A.Yu., Salamanova M.Sh., Alaskhanov A.Kh., Murtazaeva T.S.-A. Prospects for the use of cement industry waste for the production of modern concrete composites. Stroitel’nye Materialy [Construction Materials]. 2021. No. 5, pp. 55–62. (In Russian). DOI: https://doi.org/10.31659/0585-430X-2021-791-5-55-62
15. Konyukhov V.Yu., Konovalov P.N., Suslov K.V., Vasilyeva K.S. Methods of utilization and main directions of use of lignin. Molodezhnyy vestnik of IrSTU. 2015. No. 2, pp. 20–27. (In Russian).
16. Leonovich A.A., Zakharov S.S. Development of a new composite thermal insulation material using hydrolytic lignin. LesPromInform. 2015. No. 4 (110). (In Russian).
17. Tsvetkov M.V., Salgansky E.A. Lignin: directions of use and methods of disposal (review). Zhurnal prikladnoy khimii. 2018. Vol. 91. No. 7, pp. 988–997. (In Russian).
18. Volosatova K.A. Study of the possibility of using hydrolytic lignin in the production of wall blocks for low-rise construction. Inzhenernyy vestnik Dona. 2018. No. 3 (50), pp. 125–134. (In Russian).
19. Plotnikova G.P. Composite building material using wood chemical waste in its composition. Izvestiya vuzov. Investitsii. Stroitel’stvo. Nedvizhimost’. 2021. Vol. 11. No. 3 (38), pp. 452–461. (In Russian).
20. Beregovoi V.A., Egunov D.A., Sorokin D.S. Construction materials and binders based on hydrolytic lignin. Regional’naja arhitektura i stroitel’stvo. 2017. No. 3 (32), pp. 75–79. (In Russian).
21. Kiselev V.P., Ivanova L.A., Shevchenko V.A., Bugaenko M.B., Kemenev N.V. Lignin-containing polymers in asphalt concrete mixtures. Vestnik IrSTU. 2013. No. 7 (78), pp. 61–68. (In Russian).
22. Ibe E.E., Chekalova A.Yu., Shibaeva G.N. Porous ceramics based on hydrolytic lignin. Inzhenernyy vestnik Dona. 2021. No. 7 (79), pp. 311–319. (In Russian).
23. Shurysheva G.V. Lignopolymer silicate composition for protecting concrete from organogenic corrosion. Cand. Diss. (Engineering). Krasnoyarsk. 2008. 141 p. (In Russian).
24. Selivanov Yu.V., Shiltsina A.D., Selivanov V.M. Compositions and properties of ceramic heat-insulating building materials from low-temperature foaming masses based on clay raw materials. Magazine of Civil Engineering. 2012. No. 3 (29), pp. 35–40. (In Russian).
25. Xinxing Zhou, Taher Baghaee Moghaddam, Meizhu Chen, Shaopeng Wu. Life cycle assessment of biochar modified bioasphalt derived from biomass. ACS Sustainable Chemistry & Engineering. 2020. No. 8 (38), pp. 14568–14575. https://doi.org/10.1021/acssuschemeng.0c05355
26. Christian Moretti, Blanca Corona, Ric Hoefnagels. Kraft lignin as a bio-based ingredient for Dutch asphalts: an attributional LCA. Science of the Total Environment. 2022. Vol. 806. P. 1. 150316. https://doi.org/10.1016/j.scitotenv.2021.150316
27. Murtazaev S.-A.Yu., Salamanova M.Sh. Study of the durability of cement stone on non-clinker alkaline activated binders. Vestnik of the GSOTU. Technical science. 2022. Vol. 18. No. 2 (28), pp. 98–107. (In Russian).
For citation: Saidumov M.S., Murtazaev S.-A.Yu. Mezhidov D.A. Theoretical and practical aspects of the secondary use of hydrolysis productions waste in composite building materials (review). Stroitel’nye Materialy [Construction Materials]. 2023. No. 12, pp. 61–69. (In Russian). DOI: https://doi.org/10.31659/0585-430X-2023-820-12-61-69