Composite Binder for Structural Cellular Concrete


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Non-autoclaved aerated concrete is the only viable alternative to gas silicate when organizing its manufacture on the basis of regional small and medium capacity production. This aims to improvement the competitive situation on the building materials market and optimizing the construction costs. The possibility of expanding the application field of this material due to the increase in strength characteristics while maintaining an unchanged average density is of special interest. The guarantee of proposed solutions economic and technical efficiency is the transition from traditional portland cement to composite binders based on it. The article discusses the quantity and composition of the mineral supplements feasibility to optimize the binder properties of the problem peculiarities to reduce consumption of cement and chemical modifiers that increase the rate of curing and totals of non-autoclaved aerated concrete investigated compatibility issues between components to eliminate their negative impact on the formation of porous structure of the final product.



Edited by:

Dr. Denis Solovev




M.Y. Elistratkin et al., "Composite Binder for Structural Cellular Concrete", Materials Science Forum, Vol. 945, pp. 53-58, 2019

Online since:

February 2019




[1] H. Kurama, I. B. Topcu, C. Karakurt, Properties of the autoclaved aerated concrete produced from coal bottom ash, Journal of materials processing technology. 209.2 (2009) 767-773.


[2] R. Klingner. Autoclaved aerated concrete, Cambridge, UK, Woodhead, (2008).

[3] Jerman, Miloš, Hygric, thermal and durability properties of autoclaved aerated concrete, Construction and building materials. 41 (2013) 352-359.


[4] Hoff, C. George, Porosity-strength considerations for cellular concrete, Cement and Concrete Research. 2.1 (1972) 91-100.


[5] N. Narayanan, K. Ramamurthy, Structure and properties of aerated concrete: a review, Cement and Concrete composites. 22.5 (2000) 321-329.


[6] H. Esmaily, H. Nuranian, Non-autoclaved high strength cellular concrete from alkali activated slag, Construction and Building Materials. 26.1 (2012) 200-206.


[7] S. Tada, S. Nakano, Microstructural approach to properties of moist cellular concrete, Proceedings Autoclaved Aerated Concrete, Moisture and Properties. Amsterdam: Elsevier (1983) 71-89.

[8] Wan-liang ZHOU, Jing-hua LONG, Bing-gen ZHAN, Further Study on Property of Fly Ash-Fluorogypsum-Cement Composite Binder, Journal of Building Materials. 2 (2008) 13-18.

[9] Fanghui Han, Characteristics of the hydration heat evolution of composite binder at different hydrating temperature, Thermochimica Acta. 586 (2014) 52-57.


[10] N.I. Alfimova, V.V. Kalatozi, S.V. Karatsupa, Ya.Yu. Vishnevskaya, M.S. Sheychenko, Mechanoactivation as a way to increase the efficiency of using raw materials of different genesis in construction materials, Vestnik Belgorod State Technological University V.G. Shukhov. 6 (2016) 85-89.

[11] Brandt, M. Andrzej Cement-based composites: materials, mechanical properties and performance, CRC Press, (2005).

[12] N.I. Alfimova, O.V. Koval'chenko, V.V. Kalatozi, Silicified concretes and composite astringents on technogenic raw materials, Comprehensive use of technogenic raw materials, Saarbrucken (2017).

[13] R. Lesovik, Y. Degtev, M. Shakarna, A. Levchenko, Green composites in architecture and building material science, Modern Applied Science Journal. 9.1 (2015) 45-50.


[14] A.A. Kuprina, V.S. Lesovik, L.H. Zagorodnyk, M.Y. Elistratkin, Anisotropy of materials properties of natural and man-triggered origin, Research Journal of Applied Sciences. 9.11 (2014) 816-819.

[15] N.I. Alfimova, E.E. Shadskiy, R.V. Lesovik, M.S. Ageeva, Organic-mineral modifier on the basis of volcanogenic-sedimentary rocks, International Journal of Applied Engineering Research. 10.24 (2015) 45131-45136.

[16] Y.M. Bazhenov, V.T. Erofeev, V.I. Rimshin, S.V. Markov, V.L. Kurbatov, Changes in the topology of a concrete porous space in interactions with the external medium, Engineering Solid Mechanics Journal. 4.4 (2016) 219-225.


[17] V.V. Nelyubova, V.V. Strokova, A.B. Buchalo, Non-autoclaved cellular composites with nanocomponents, Composition, structure, properties, Saarbrucken. (2017) 565-572.

[18] M.N. Sivalneva, N.V. Pavlenko, P.P. Pastushkov, V.V. Strokova, D.D. Netsvet, N.A. Shapovalov, Steam curing characteristics of cellular concrete on the base of nanostructured binder, Journal of Fundamental and Applied Sciences. 8.38 (2016) 1480-1488.

[19] N.I. Alfimova, V.S. Lesovik, E.S. Glagolev, Ya.Yu Vishnevskaya, Optimization of the curing conditions for composite astringents taking into account the genesis of the silica-containing component, Belgorod, (2016).

[20] M.S. Ageeva, N.I. Alfimova, Effective composite binder based on man-made raw materials, Saarbrucken. (2015).

[21] R.V. Lesovik, S.I. Leshchev, M.S. Ageeva, S.V. Karatsupa, N.I. Alfimova, The use of zeolite-containing rottenstone powder for the composite binding production, International Journal of Applied Engineering Research. 10.24 (2015) 44889.