How to cite this paper
Bazhenov, Y., Erofeev, V., Rimshin, V., Markov, S & Kurbatov, V. (2016). Changes in the topology of a concrete porous space in interactions with the external medium.Engineering Solid Mechanics, 4(4), 219-225.
Refrences
Alekseev, S. N. (1993). Durability of reinforced concrete in aggressive media (Vol. 96). AA Balkema Publishers.
Bazhenov, Y.M. (2002). Concrete topology Manual. Moscow: ACB.
Cebeci, O.Z. (1986). Hydration and porosity of cement paste cured in warm and dry environments, 8th International Congress on the on the Chemistry of Cement, Sept. 22-27, Rio de Janeiro, Brasil, vol. 3 (2.2), 412 – 416
Dobrolyubov, G., Ratinov, V.B., & Rosenberg, T.I. (1983). The prediction of durability of concrete. Moscow.
Dvorkin, L. I., & Dvorkin, O. L. (2007). Building materials from waste the Industrial Training handbook Rostov n/D: Phoenix,-368 p. Building.[in Russian].
Lomachenko, D.V. (2014). Rheological properties research of cement paste with superplasticizing agent for concrete SB-3. Modern Science-Incentive Technologies, 2, 123.
Furmanov, N.E. (2009). Favorable composition of the concrete for the manufacture of waterproof structures according to the “White tub”. Civil Engineering Journal, 3, 11-16.
Kosuhin M.M., Poluektova V.A., Malinovka V.M., & Shapovalov N.A. (2013). Polyfunctional super plasticizer for concretes based on pyrocatechin production waste products. Fundamental Research, 3(1), 718-722.
Krasovskii P.F. (2013). Physical-chemical principles of formation of structure of cement concretes. Khabarovsk: Publishing house FESTU.
Kurbatov V.I., Sereda O.A., & Danilyan E.A. (2010). The dilatometric method of testing concrete. Diagnostics of materials, 6; 61-63.
Liang, M. T., & Lin, S. M. (2003). Mathematical modeling and applications for concrete carbonation. Journal of Marine Science and Technology, 11(1), 20-33.
Meland, I. (1985). Carbonation effects in hardened fly ash cements. In MRS Proceedings (Vol. 65, p. 199). Cambridge University Press.
Meier, S. A., Peter, M. A., Muntean, A., & Böhm, M. (2007). Dynamics of the internal reaction layer arising during carbonation of concrete. Chemical Engineering Science, 62(4), 1125-1137.
Mindess, S. (2006). Advanced concrete for use in civil engineering. Advanced Civil Infrastructure Materials, 1-29.
Neville, A. M. (1995). Properties of concrete.
Novichkov, P.I. (2001). On diffusion kinetics of reactions in concrete. Proceedings of the Jubilee Conference, Moscow: PAACH.
Orchard, D. F., Curran, A., & Hearne, R. (1979). Concrete Technology: Properties of Materials. 1, (No. Monograph).
Osherov – Marshak, A. (2002). Methodological aspects of modern concrete technology. Concrete and Reinforced concrete, 11, 5-7.
Papadakis, V. G., & Efstathiou, M. P. (2006) Field Validation of a Computer-based Prediction for Concrete Service Life.
Sagneva E.A., Martakov I., Dmitrienko R.A. & Dmitrienko C. (2012). Analysis of the state of mixing equipment for concrete and mortar mixes. Energy-saving technological systems and equipment for manufacture of building materials: interuniversity collection of articles, 11, 315-317.
Solomatov V.I., & Tahir M.K. (1989). Tucker Shah Md. The intensive technology of concrete, Moscow: Stroiizdat.
Stol`nikov, V.V. (1953). Air entraining additives in hydraulic concrete. Leningrad: Gosenergoizdat.
Ramachandran, V. S., Feldman, R. F., & Beaudoin, J. J. (1981). Concrete Science: Treatise on Current Research, Heyden and Son. Ltd., Philadelphia.
Ureckaya, E.A., & Batyanowski, E.I. (2001). Dry mix: materials and technologies. Minsk; Strinko.
Vlasov, V.K. (1998). Regularities optimization of structure of concrete with dis - dispersed mineral additives. Concrete and Reinforced Concrete, 4, 10-12.
Wu, S.H. (2006). Advanced cement composites for use in civil engineering. Science, Mechanics and Applications, 63-117.
Bazhenov, Y.M. (2002). Concrete topology Manual. Moscow: ACB.
Cebeci, O.Z. (1986). Hydration and porosity of cement paste cured in warm and dry environments, 8th International Congress on the on the Chemistry of Cement, Sept. 22-27, Rio de Janeiro, Brasil, vol. 3 (2.2), 412 – 416
Dobrolyubov, G., Ratinov, V.B., & Rosenberg, T.I. (1983). The prediction of durability of concrete. Moscow.
Dvorkin, L. I., & Dvorkin, O. L. (2007). Building materials from waste the Industrial Training handbook Rostov n/D: Phoenix,-368 p. Building.[in Russian].
Lomachenko, D.V. (2014). Rheological properties research of cement paste with superplasticizing agent for concrete SB-3. Modern Science-Incentive Technologies, 2, 123.
Furmanov, N.E. (2009). Favorable composition of the concrete for the manufacture of waterproof structures according to the “White tub”. Civil Engineering Journal, 3, 11-16.
Kosuhin M.M., Poluektova V.A., Malinovka V.M., & Shapovalov N.A. (2013). Polyfunctional super plasticizer for concretes based on pyrocatechin production waste products. Fundamental Research, 3(1), 718-722.
Krasovskii P.F. (2013). Physical-chemical principles of formation of structure of cement concretes. Khabarovsk: Publishing house FESTU.
Kurbatov V.I., Sereda O.A., & Danilyan E.A. (2010). The dilatometric method of testing concrete. Diagnostics of materials, 6; 61-63.
Liang, M. T., & Lin, S. M. (2003). Mathematical modeling and applications for concrete carbonation. Journal of Marine Science and Technology, 11(1), 20-33.
Meland, I. (1985). Carbonation effects in hardened fly ash cements. In MRS Proceedings (Vol. 65, p. 199). Cambridge University Press.
Meier, S. A., Peter, M. A., Muntean, A., & Böhm, M. (2007). Dynamics of the internal reaction layer arising during carbonation of concrete. Chemical Engineering Science, 62(4), 1125-1137.
Mindess, S. (2006). Advanced concrete for use in civil engineering. Advanced Civil Infrastructure Materials, 1-29.
Neville, A. M. (1995). Properties of concrete.
Novichkov, P.I. (2001). On diffusion kinetics of reactions in concrete. Proceedings of the Jubilee Conference, Moscow: PAACH.
Orchard, D. F., Curran, A., & Hearne, R. (1979). Concrete Technology: Properties of Materials. 1, (No. Monograph).
Osherov – Marshak, A. (2002). Methodological aspects of modern concrete technology. Concrete and Reinforced concrete, 11, 5-7.
Papadakis, V. G., & Efstathiou, M. P. (2006) Field Validation of a Computer-based Prediction for Concrete Service Life.
Sagneva E.A., Martakov I., Dmitrienko R.A. & Dmitrienko C. (2012). Analysis of the state of mixing equipment for concrete and mortar mixes. Energy-saving technological systems and equipment for manufacture of building materials: interuniversity collection of articles, 11, 315-317.
Solomatov V.I., & Tahir M.K. (1989). Tucker Shah Md. The intensive technology of concrete, Moscow: Stroiizdat.
Stol`nikov, V.V. (1953). Air entraining additives in hydraulic concrete. Leningrad: Gosenergoizdat.
Ramachandran, V. S., Feldman, R. F., & Beaudoin, J. J. (1981). Concrete Science: Treatise on Current Research, Heyden and Son. Ltd., Philadelphia.
Ureckaya, E.A., & Batyanowski, E.I. (2001). Dry mix: materials and technologies. Minsk; Strinko.
Vlasov, V.K. (1998). Regularities optimization of structure of concrete with dis - dispersed mineral additives. Concrete and Reinforced Concrete, 4, 10-12.
Wu, S.H. (2006). Advanced cement composites for use in civil engineering. Science, Mechanics and Applications, 63-117.