"Вестник МГСУ"

The authors have completed a research into the influence of wollastonite onto the strength of the cement stone, if the latter is freshly made or stored in the humid environment for four months. The authors believe that the optimal share of the wollastonite admixture is equal to 5…9 %.The strength of wollastonite-free clinker samples is not reduced, if the clinker is stored in the humid environment and exposed to heat and moisture treatment. Upon the expiry of the 28-days’ curing period, the strength of samples is down by 4 % in the regular environment. In this case, the wollastonite admixture (7 %) improves the strength of samples upon the expiry of the 28 days’ curing period and their strength goes up by28 %, while the strength of samples goes up by 17 % upon their exposure to heat and moisture treatment.The authors believe that the influence produced by wollastonite may be explained by the following reasons. In the event that freshly milled powder (clinker) is added, wollastonite produces its influence on the hydration process, as formation of new compounds (hydrates) is influenced by a strong adsorption field of wollastonite particles.If clinker is stored in the humid environment, its substantial share is subject to hydration and carbonization.

The article presents the procedure of interaction between the water and the particles of the cement binding agent, if subjected to high-speed processing inside an intensive mixing device that represents a hydrodynamic stirrer composed of a rotor and variable section turbines. The proposed method of modification (mechanical activation) of the cement and water suspension makes it possible to reduce the cost of concrete due to reduction of the cement consumption rate. The research of strength-related properties of the cement stone has proven that high-speed mechanical processing of the binding agent, if mixed with the water, may improve mechanical properties of concrete by 25 to 30 %.

The article is devoted to the investigation of chemical composition of cement stone modified by micro- and nanoscale barium hydrosilicates. It is shown that introduction of a nanomodifier leads to increased amount of various calcium hydrosilicates, lowers the amount of portlandite and calcium hydrosulfoaluminates. The specifics of influence of various barium hydrosilicates on the chemical composition of cement stone is revealed. It is shown that sol made of precursor with the content of С(Fe(OH)3) = 0.7 %, α = 1.0 (that was stored for 28 days) is the most effective among all other examined nanomodifiers. This can be due to the specific values of silicic acid concentration in the modifier and also by pH value of the medium; other factors may also affect the efficiency. Because of different content of silicic acid the modification of the portland cement by micro-sized barium hydrosilicates decreasesthe amount of portlandite (about two times). The sequential modification with nano- and micro-scale modifiers allows reducing the amount of portlandite by 3.67…60.5 times. Thus, nanomodification of the previously optimized (at the micro scale) cement composite (cement stone) is the most effective. High efficiency of the sol that was made of precursor with the content of С(Fe(OH)3) = 0.5 %, α = 1.5 is also observed. During our experiments we have also revealed the distinctive feature of the nanomodification of cement stone. This feature consists in content growth for specific type of calcium hydrosilicates. In particular, by means of using the sol that was made of precursor with the content of С(Fe(OH)3) = 0.5-0.7 %, α = 1.0, the amount of silicon-oxygen tetrahedrons can be magnified; the relative amount of silicon-oxygen ν(SiO) chains can also be increased in case of α = 1.5.

The paper deals with the development of composite binders for producing concrete with improved characteristics of gas, water and vapor permeability. The authors investigate the processes of composite materials formation in order of decreasing scale levels from macro to nanostructures. The criteria for optimization of the volume of dispersed additives in concrete are offered. The authors theoretically studied the technological features of the formation of hydrated cement stone structure. A positive effect of nanodispersed additives on the structure and physico-mechanical properties of cement composite materials are predicted. Thanks to its improved features, such as good ratio of strength and body density, high density and lifetime, the modified concrete may be used when solving various practical tasks of the construction branch.