How to cite this paper
Bazhenov, Y., Murtazaev, S., Bataev, D., Alaskhanov, A., Murtazaeva, T & Saydumov, M. (2021). High-strength concretes based on anthropogenic raw materials for earthquake resistant high-rise construction.Engineering Solid Mechanics, 9(3), 335-346.
Refrences
Aitcin, P.C. (1998). High-performance concrete. London: E&FN SPON.
Alekseev, V.A., Bazhenov, Yu.M., Bazhenova, S.I., Bazhenova, O.Yu., Golovashchenko, N.A., & Mironchuk, N.S. (2018). Modified binder for sprayed concrete. BST: Byulleten' stroitel'noi tekhniki, 5(1005), 18-19.
Barabash, I., & Zubchenko, N. (2015). Properties of concrete on activated composite binders. Vestnik Donbasskoi natsional'noi akademii stroitel'stva i arkhitektury, 1(111), 9-11.
Bartoleto, A.P. (2015). Waste prevention policy and behaviour. New approaches to reducing waste generation and its environmental impacts. Routledge studies in waste management and policy. New York: Routledge.
Bataev, D.K-S., Saidumov, M.S., Murtazaeva, T.S-A., Dudaev, D.M., & Salgiriev, M.K. (2017). Retseptury vysokoprochnykh betonov na tekhnogennom i prirodnom syr'e [Recipes of high-strength concretes based on anthropogenic and natural raw materials]. Urgent issues of modern construction science and education. Proceedings: All-Russian Conference devoted to the 60th anniversary of Construction faculty (Grozny State Oil Technical University), pp. 109-117.
Bazhenov, Yu.M. (2011). Tekhnologiya betona [Technology of concrete]. Moscow: ASV.
Berg, O.Ya., Shcherbakov, E.N., & Pisanko, G.N. (2012). Vysokoprochnyi beton [High-strength concrete]. Moscow: Stroiizdat.
Dem'yanova, V.S. (2013). Effektivnye stroitel'nye materialy s ispol'zovaniem tekhnogennykh otkhodov [Efficient construction materials based on anthropogenic wastes]. Penza: PGUAS.
Kaprielov, S.S., Sheinfel'd, A.V., & Dondukov, V.G. (2017). Tsementy i dobavki dlya proizvodstva vysokoprochnykh betonov [Cements and additives for production of high-strength concretes]. Stroitel'nye materialy, 11, 4-10.
Kapustin, F.L., Perepelitsyn, V.A., & Ponomarev, V.B. (2017). Enhancing efficiency of rock crushing screening utilization. Journal of Mining Science, 53(3), 519-523.
Kim, J.-K., & Kim, Y.-Y. (1996). Experimental study of the fatigue behavior of high strength concrete. Cement and Concrete Research, 26(10), 1513-1523.
Kuprina, A.A., Lesovik, V.S., Zagorodnyk, L.H., & Elistratkin, M.Y. (2014). Anisotropy of materials properties of natural and man-triggered origin. Research Journal of Applied Sciences, 9(11), 816-819.
Lesovik, V., Volodchenko, A., Glagolev, E., Lashina, I., & Fischer, H.B. (2019). Geonics (geomimetics) as a theoretical basis for new generation compositing. In: 14th International Congress for Applied Mineralogy (ICAM2019) Series “Springer Proceedings in Earth and Environmental Sciences”, pp. 344-347.
Lesovik, V.S., Murtazayev, S-A.Yu., Saydumov, M.S. (2012). Stroitelnyye kompozity na osnove otsevov drobleniya betonnogo loma i gornykh porod: nauchnoye izdaniye [Building composites based on screenings for crushing concrete scrap and rocks: scientific publication]. Grozny: Municipal Unitary Enterprise “Printing House”.
Mohajerani, A., Suter, D., & Jeffrey-Bailey, T. (2019). Recycling waste materials in geopolymer concrete. Clean Technologies and Environmental Policy, 21(3), 493-515.
Murtazaev, S.A., Saydumov, M., Alaskhanov, A., & Nakhaev, M. (2019). High-quality concretes for foundations of the multifunctional high-rise complex(MHC) "Akhmat Tower". In: 14th International Congress for Applied Mineralogy (ICAM2019); Series “Springer Proceedings in Earth and Environmental Sciences”, pp. 365-368.
Murtazaev, S-A.Y., Zaurbekov, Sh.Sh., Alaskhanov, A.Kh., Saydumov, M.S., Murtazaeva, T.S-A., & Khadzhiev, M.R. (2018). Impact of Technogenic Raw Materials on the Properties of High-Quality Concrete Composites. International Symposium “Engineering and Earth Sciences: Applied and Fundamental Research” (ISEES 2018). Advances in Engineering Research, 177, 275-279.
Nesvetaev, G.V., Nalimova, A.V., & Chmel', G.V. (2003). Otsenka effektivnosti superplastifikatorov dlya vysokoprochnykh i vysokokachestvennykh betonov [Estimation of efficiency of super-plasticizing agents for high-strength and high-quality concretes]. Izvestiya VUZov: Stroitel'stvo, 9, 38-41.
Olzvoibaatar, L. (2019). Some results of study for processing concrete with environment-friendly using filler of waste concrete. Innovative approaches in modern science: Collection of articles, LIV International Conference, pp. 105-110.
Patil, S.B., Vyas, A.K., Gupta, A.B., & Patil, R.S. (2016). Imperial smelting furnace slag as fine aggregate in cement concrete mixes. Journal of Solid Waste Technology and Management, 42(2), 128–136.
Piatak, N.M., Parsons, M.B., & Seal, R.R. (2015). Characteristics and environmental aspects of slag: a review. Applied Geochemistry, 57, 236-266.
Rakhimbayev, S.M., Tolypina, N.M., & Khakhaleva, E.N. (2016). Filler adhesion theory by cement stone. International Journal of Pharmacy and Technology, 8(4), 24938-24946.
Richard, P., & Cheyrezy, M. (1995). Composition of reactive powder concretes. Cement and Concrete Research, 25, 1501–1511.
Rooholamini, H., Hassani, A., & Aliha, M. R. M. (2018a). Fracture properties of hybrid fibre-reinforced roller-compacted concrete in mode I with consideration of possible kinked crack. Construction and Building Materials, 187, 248-256.
Rooholamini, H., Hassani, A., & Aliha, M. R. M. (2018b). Evaluating the effect of macro-synthetic fibre on the mechanical properties of roller-compacted concrete pavement using response surface methodology. Construction and Building Materials, 159, 517-529.
Shadykanov, K. (2019). Improving the efficiency of manufacturing fine-grained concrete through the use of man-made sands and composite binders. ARPN Journal of Engineering and Applied Sciences, 14(18), 3284-3288.
Sharifi, E., Sadjadi, S. J., Aliha, M. R. M., & Moniri, A. (2020). Optimization of high-strength self-consolidating concrete mix design using an improved Taguchi optimization method. Construction and Building Materials, 236, 117547.
Shi, C., Wu, Z., Xiao, J., Wang, D., Huang, & Z., Fang, Z. (2015). A review on ultra-high-performance concrete: Part 1. Raw materials and mixture design. Construction and Building Materials, 101, 741–751.
Skazlic, M., & Bjegovic, D. (2005). Perspectives of designing with new concrete types. Zagreb: Annual 2005 of the Croatian Academy of Engineering, pp. 167-178.
Suleymanova, L.A., Lesovik, V.S., Kara, K.A., Malyukova, M.V., & Suleymanov, K.A. (2014). Energy-efficient concretes for green construction. Research Journal of Applied Sciences, 9(12), 1087-1090.
Volkov, Yu., & Zvezdov, A. (2004). Beton osnova dlya sovremennykh neboskrebov [Concrete as base for modern high-rise buildings]. Stroitel'stvo, 5, 56-59.
Volodchenko, A.A., Lesovik, V.S., Zagorodnjuk, L.H., & Volodchenko, A.N. (2015). Influence of the inorganic modifier structure on structural composite properties. International Journal of Applied Engineering Research, 10(19), 40617-40622.
Volodchenko, A.A., Lesovik, V.S., Zagorodnjuk, L.H., Volodchenko, A.N., & Aleksandrovna, K.A. (2016). The control of building composite structure formation through the use of multifunctional modifiers. Research Journal of Applied Sciences, 10(12), 931-936.
Alekseev, V.A., Bazhenov, Yu.M., Bazhenova, S.I., Bazhenova, O.Yu., Golovashchenko, N.A., & Mironchuk, N.S. (2018). Modified binder for sprayed concrete. BST: Byulleten' stroitel'noi tekhniki, 5(1005), 18-19.
Barabash, I., & Zubchenko, N. (2015). Properties of concrete on activated composite binders. Vestnik Donbasskoi natsional'noi akademii stroitel'stva i arkhitektury, 1(111), 9-11.
Bartoleto, A.P. (2015). Waste prevention policy and behaviour. New approaches to reducing waste generation and its environmental impacts. Routledge studies in waste management and policy. New York: Routledge.
Bataev, D.K-S., Saidumov, M.S., Murtazaeva, T.S-A., Dudaev, D.M., & Salgiriev, M.K. (2017). Retseptury vysokoprochnykh betonov na tekhnogennom i prirodnom syr'e [Recipes of high-strength concretes based on anthropogenic and natural raw materials]. Urgent issues of modern construction science and education. Proceedings: All-Russian Conference devoted to the 60th anniversary of Construction faculty (Grozny State Oil Technical University), pp. 109-117.
Bazhenov, Yu.M. (2011). Tekhnologiya betona [Technology of concrete]. Moscow: ASV.
Berg, O.Ya., Shcherbakov, E.N., & Pisanko, G.N. (2012). Vysokoprochnyi beton [High-strength concrete]. Moscow: Stroiizdat.
Dem'yanova, V.S. (2013). Effektivnye stroitel'nye materialy s ispol'zovaniem tekhnogennykh otkhodov [Efficient construction materials based on anthropogenic wastes]. Penza: PGUAS.
Kaprielov, S.S., Sheinfel'd, A.V., & Dondukov, V.G. (2017). Tsementy i dobavki dlya proizvodstva vysokoprochnykh betonov [Cements and additives for production of high-strength concretes]. Stroitel'nye materialy, 11, 4-10.
Kapustin, F.L., Perepelitsyn, V.A., & Ponomarev, V.B. (2017). Enhancing efficiency of rock crushing screening utilization. Journal of Mining Science, 53(3), 519-523.
Kim, J.-K., & Kim, Y.-Y. (1996). Experimental study of the fatigue behavior of high strength concrete. Cement and Concrete Research, 26(10), 1513-1523.
Kuprina, A.A., Lesovik, V.S., Zagorodnyk, L.H., & Elistratkin, M.Y. (2014). Anisotropy of materials properties of natural and man-triggered origin. Research Journal of Applied Sciences, 9(11), 816-819.
Lesovik, V., Volodchenko, A., Glagolev, E., Lashina, I., & Fischer, H.B. (2019). Geonics (geomimetics) as a theoretical basis for new generation compositing. In: 14th International Congress for Applied Mineralogy (ICAM2019) Series “Springer Proceedings in Earth and Environmental Sciences”, pp. 344-347.
Lesovik, V.S., Murtazayev, S-A.Yu., Saydumov, M.S. (2012). Stroitelnyye kompozity na osnove otsevov drobleniya betonnogo loma i gornykh porod: nauchnoye izdaniye [Building composites based on screenings for crushing concrete scrap and rocks: scientific publication]. Grozny: Municipal Unitary Enterprise “Printing House”.
Mohajerani, A., Suter, D., & Jeffrey-Bailey, T. (2019). Recycling waste materials in geopolymer concrete. Clean Technologies and Environmental Policy, 21(3), 493-515.
Murtazaev, S.A., Saydumov, M., Alaskhanov, A., & Nakhaev, M. (2019). High-quality concretes for foundations of the multifunctional high-rise complex(MHC) "Akhmat Tower". In: 14th International Congress for Applied Mineralogy (ICAM2019); Series “Springer Proceedings in Earth and Environmental Sciences”, pp. 365-368.
Murtazaev, S-A.Y., Zaurbekov, Sh.Sh., Alaskhanov, A.Kh., Saydumov, M.S., Murtazaeva, T.S-A., & Khadzhiev, M.R. (2018). Impact of Technogenic Raw Materials on the Properties of High-Quality Concrete Composites. International Symposium “Engineering and Earth Sciences: Applied and Fundamental Research” (ISEES 2018). Advances in Engineering Research, 177, 275-279.
Nesvetaev, G.V., Nalimova, A.V., & Chmel', G.V. (2003). Otsenka effektivnosti superplastifikatorov dlya vysokoprochnykh i vysokokachestvennykh betonov [Estimation of efficiency of super-plasticizing agents for high-strength and high-quality concretes]. Izvestiya VUZov: Stroitel'stvo, 9, 38-41.
Olzvoibaatar, L. (2019). Some results of study for processing concrete with environment-friendly using filler of waste concrete. Innovative approaches in modern science: Collection of articles, LIV International Conference, pp. 105-110.
Patil, S.B., Vyas, A.K., Gupta, A.B., & Patil, R.S. (2016). Imperial smelting furnace slag as fine aggregate in cement concrete mixes. Journal of Solid Waste Technology and Management, 42(2), 128–136.
Piatak, N.M., Parsons, M.B., & Seal, R.R. (2015). Characteristics and environmental aspects of slag: a review. Applied Geochemistry, 57, 236-266.
Rakhimbayev, S.M., Tolypina, N.M., & Khakhaleva, E.N. (2016). Filler adhesion theory by cement stone. International Journal of Pharmacy and Technology, 8(4), 24938-24946.
Richard, P., & Cheyrezy, M. (1995). Composition of reactive powder concretes. Cement and Concrete Research, 25, 1501–1511.
Rooholamini, H., Hassani, A., & Aliha, M. R. M. (2018a). Fracture properties of hybrid fibre-reinforced roller-compacted concrete in mode I with consideration of possible kinked crack. Construction and Building Materials, 187, 248-256.
Rooholamini, H., Hassani, A., & Aliha, M. R. M. (2018b). Evaluating the effect of macro-synthetic fibre on the mechanical properties of roller-compacted concrete pavement using response surface methodology. Construction and Building Materials, 159, 517-529.
Shadykanov, K. (2019). Improving the efficiency of manufacturing fine-grained concrete through the use of man-made sands and composite binders. ARPN Journal of Engineering and Applied Sciences, 14(18), 3284-3288.
Sharifi, E., Sadjadi, S. J., Aliha, M. R. M., & Moniri, A. (2020). Optimization of high-strength self-consolidating concrete mix design using an improved Taguchi optimization method. Construction and Building Materials, 236, 117547.
Shi, C., Wu, Z., Xiao, J., Wang, D., Huang, & Z., Fang, Z. (2015). A review on ultra-high-performance concrete: Part 1. Raw materials and mixture design. Construction and Building Materials, 101, 741–751.
Skazlic, M., & Bjegovic, D. (2005). Perspectives of designing with new concrete types. Zagreb: Annual 2005 of the Croatian Academy of Engineering, pp. 167-178.
Suleymanova, L.A., Lesovik, V.S., Kara, K.A., Malyukova, M.V., & Suleymanov, K.A. (2014). Energy-efficient concretes for green construction. Research Journal of Applied Sciences, 9(12), 1087-1090.
Volkov, Yu., & Zvezdov, A. (2004). Beton osnova dlya sovremennykh neboskrebov [Concrete as base for modern high-rise buildings]. Stroitel'stvo, 5, 56-59.
Volodchenko, A.A., Lesovik, V.S., Zagorodnjuk, L.H., & Volodchenko, A.N. (2015). Influence of the inorganic modifier structure on structural composite properties. International Journal of Applied Engineering Research, 10(19), 40617-40622.
Volodchenko, A.A., Lesovik, V.S., Zagorodnjuk, L.H., Volodchenko, A.N., & Aleksandrovna, K.A. (2016). The control of building composite structure formation through the use of multifunctional modifiers. Research Journal of Applied Sciences, 10(12), 931-936.