Non-Autoclaved Aerated Concrete on the Basis of Composite Binder Using Technogenic Raw Materials

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Non-autoclaved aerated concrete certain advantages are significantly lower production organization costs and technology energy intensity due to the lack of autoclave curing, the possibility of different scales industries foundation as well as monolithic construction applications. All of this allows to solve complex problems of various purposes buildings erection, heat and noise insulation. Portland cement consumption significant reduction and material properties management can be achieved through use of composite binders containing local natural and technogenic components selected on the basis of their genesis and properties. The applicability of heavy concrete and ceramic bricks processing wastes as well as such large-tonnage extraction of iron ore as sandstones granulation selection as mineral additive for non-autoclaved aerated concrete production as well as a number of accompanying issues of the of a high-quality pore space structures formation control are considered in the present article.

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Edited by:

Dr. Denis Solovev

Pages:

205-211

Citation:

V. S. Lesovik et al., "Non-Autoclaved Aerated Concrete on the Basis of Composite Binder Using Technogenic Raw Materials", Materials Science Forum, Vol. 945, pp. 205-211, 2019

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February 2019

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$41.00

[1] Y. Bazhenov, S.-A. Murtazaev, M. Salamanova, M. Saidumov, High-performance SCC-concrete at earthquake resistant construction, International Journal of Environmental and Science Education. 11.18 (2016) 12779-12786.

[2] V.S. Lesovik, O.V. Puchka, S.S. Waisera, M.Yu. Elistratkin, New Generation of Building Composites Based on Foam Glass, Construction and Reconstruction. 3.59 (2015) 146-154.

[3] K.A. Kara, To the question of the technical and economic efficiency of non-autoclaved cellular concrete, Regional architecture and construction. 4.29 (2016) 20-27.

[4] V.R. Serdyuk, Cellular concrete as an important component of the construction of energy-saving housing in the CIS countries, In the collection: Innovative development of territories Materials of the III International Scientific and Practical Conference. (2015) 21-23.

[5] W.S. Lessowik, Geonik. Geomimetik als grundlage für die synthese von intelligent bauverbundwerkstoffen, 19 Internationale baustofftagung IBAUSIL. (2015) 183-189.

[6] L.A. Suleimanova, K.A. Suleimanov, I.A. Pogorelova, Topology of pores in aerated concrete, Bulletin of the Belgorod State Technological University named after. V.G. Shukhov. 5 (2016) 100-105.

[7] T.T. Nguyen, D.V. Oreshkin, A study of the structure of aerated concrete for the housing construction of Vietnam, Scientific and Technical Herald of the Volga Region. 3 (2014) 169-172.

[8] M.Ya. Bikbau., V.N. Mochalov, Chen Lun, Production of mechanically and chemically activated cements (binding agents) of low water demand, Cement and its application. 3 (2008) 80-89.

[9] Y.M. Bazhenov, L.H. Zagorodnjuk, V.S. Lesovik, I.V. Yerofeyeva, N.V. Chernysheva, D.A. Sumskoy, Сoncerning the role of mineral additives in composite binder content, International Journal of Pharmacy and Technology. 8.4 (2016) 22649-22661.

[10] A.A. Kuprina, V.S. Lesovik, M.Yu. Elistratkin, A.V. Ginzburg, Composite binders for effective mortars, Belgorod, (2015).

[11] N.I. Alfimova, M.S. Sheychenko, S.V. Karatsupa, E.A. Yakovlev, A.S. Kolomatskiy, N.N. Shapovalov, Features of application of high-mg technogenic raw materials as a component of composite binders, Research Journal of Applied Sciences. 9.11 (2014) 779-783.

[12] N.I. Alfimova, V.S. Lesovik, A.V. Savin, E.E. Shadsky Prospects for the application of composite binders in the manufacture of reinforced concrete products, Vestnik of the Irkutsk State Technical University. 5.88 (2014) 95-99.

[13] V.S. Lesovik, L.A. Suleimanova, K.A. Kara, Energy-efficient aerated concrete on composite binders for monolithic construction, Izvestiya Vysshikh Uchebnykh Zavedenii. Building. 3 (2012) 10-20.

[14] A.N. Volodchenko, V.S. Lesovik, Rheological properties of a gas-concrete mixture on the basis of non-traditional raw materials, Bulletin of the Belgorod State Technological University named after VG Shukhov. 3 (2012) 45-48.

DOI: https://doi.org/10.12737/24452

[15] L.A. Suleimanova, I.A. Pogorelova, K.R. Kondrashev, K.A. Suleimanov, Yu.S. Piriyev, Energy-saving aerated concrete on composite astringents, Bulletin of the Belgorod State Technological University named after V.G. Shukhov. 4 (2016) 73-83.

[16] 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.

DOI: https://doi.org/10.1016/j.jmatprotec.2008.02.044

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

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

DOI: https://doi.org/10.1016/j.conbuildmat.2012.12.036

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

DOI: https://doi.org/10.1016/0008-8846(72)90026-9

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

DOI: https://doi.org/10.1016/s0958-9465(00)00016-0

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

DOI: https://doi.org/10.1016/j.conbuildmat.2011.06.010