AbstractAbout AuthorsReferences
Physical-chemical and structural-technological bases of producing high-strength and high-durable structural lightweight concretes (HSLC) necessary for determination of their optimal compositions and regulated parameters have been developed. Conditions of the formation of optimal structure of these concretes including the contact zone of concrete components have been defined by the experimental-theoretical way (with the help of structural-simulation models). Technological bases for using results of these studies for development of optimal compositions of HSLC with optimal regulated parameters have been formulated
V.N. YARMAKOVSKY, Candidate of Sciences (Engineering), Honorary member of RAACS (This email address is being protected from spambots. You need JavaScript enabled to view it.)
Scientific-Research Institute of Building Physics of the Russian Academy architecture and construction sciences (RAACS) (21, Lokomotivniy Driveway, Moscow, 127238, Russian Federation)
1. Karpenko N.I., Yarmakovskiy V.N. To the Standardization of Physical-Mechanical Properties of High Strength Lightweight Aggregate Concrete and to the Calculation Methods of Structures Made of them Zhilishchnoe Stroitel’stvo [Housing Construction]. 2016. No. 7, pp. 25–28. (In Russian).
2. Petrov V.P., Makridin N.I., Sokolova Yu.A., Yarmakovskii V.N. Tekhnologiya i materialovedenie poristykh zapolnitelei i legkikh betonov. Monografiya [Technology and materials porous aggregates and lightweight concrete. Monograph]. Moscow: “Paleotip”: RAACS. 2013. 332 p.
3. Simonov M.Z. Osnovy tekhnologii legkikh betonov [Technology basics of lightweight concrete]. Moscow: Stroyizdat. 1973. 583 p.
4. Orentlikher L.P. Betony na poristykh zapolnitelyakh v sbornykh zhelezobetonnykh konstruktsiyakh [Concrete with porous aggregates in precast concrete structures]. Moscow: Stroyizdat. 1983. 144 p.
5. Krasil’nikov K.G., Nikitina L.V., Skoblinskaya N.N. Fizikokhimiya sobstvennykh deformatsii tsementnogo kamnya [Physical chemistry of its own strain of cement paste]. Moscow: Stroyizdat. 1980. 252 p.
6. Akhverdov I.N. Osnovy fiziki betona [Fundamentals of physics concrete]. Moscow: Stroyizdat. 1981. 456 p.
7. Kosmatka S.H., Kerkhoff B. Design and Control of Concrete Mixtures. Guide to Application, Methods, and Materials. Ottawa, Cement Association of Canada, 2011, 411 p.
8. FIP Manual of Lightweight Aggregate Concrete. Third Edition. Glasgow and London. Surrey University Press. 2003. 255 p.
9. Yarmakovsky V.N., Pustovgar A.P. The scientific basis for the creation of a composite binders class, characterized of the low heat conductivity and low sorption activity of cement stone. Proceeding of XXIV R-S-P seminar. Theoretical Foundation of Civil Engineering (24RSP). Procedia Engineering. 2015. 111, pp. 864–870.
10. Kaushanskiy V.E. The use of man-made materials in the manufacture of cement. Proceedings of the International scientific-practical conference “Science and technology of silicate materials – present and future date.” MUCTR. D.I. Mendeleev. 14–17 oct. 2003, pp. 36–50. (In Russian).
11. Karpenko N.I., Yarmakovskiy V.N., Shkol’nik Ya.Sh. Status and prospects of the processed products of man-made structures in the construction industry. Ekologiya i promyshlennost’ Rossii. 2012. No. 10, pp. 50–54. (In Russian).
12. Butt Yu.M., Maier A.A., Marshal B.G. Hydration mineralogical components of blast furnace slag. In the book: Questions of slag. Proceedings of the Chelyabinsk “PromstroyNIIproekt”. 1960, pp. 418–446. (In Russian).
13. Gorshkov V.S., Aleksandrov S.E., Ivashchenko S.I., Gorshkova I.V. Kompleksnaya pererabotka i ispol’zovanie metallurgicheskikh shlakov v stroitel’stve [Complex processing and utilization of metallurgical slag in construction]. Moscow: Stroyizdat. 1985. 273 p.
14. Gemmerling G.V., Tsimermanis L.B. Shlakopemzobeton. [Shlakopemzobeton. Moscow: Stroyizdat. 1969. 135 p.
15. Botvinkin O.K. Fizicheskaya khimiya silikatov [Physical chemistry of silicates]. Moscow: Stroyizdat. 1955. 287 p.
16. Yarmakovskiy V.N On the method of calculation of reinforced concrete structures increased frost resistance. Proceedings NIIZhB “Improving the durability of concrete and reinforced concrete when exposed to aggressive environments”. Moscow: Gosstroi SSSR Stroyizdat. 1975. pp. 34–38. (In Russian).
17. Zaitsev Yu.V. Modelirovanie deformatsiy i prochnosti betona metodami mekhaniki razrusheniya [Simulation of deformation and strength of concrete methods of fracture mechanics]. Moscow: Stroyizdat. 1982. 196 p.
18. Karpenko N.I. Obshchie modeli mekhaniki zhelezobetona [General mechanics model of reinforced concrete]. Moscow: Stroyizdat. 1996. 208 p.
19. Patent RF 2421421. Modifikator betona i sposob ego polucheniya [Modifier concrete and its production method]. Yarmakovskiy V.N., Torpishchev Sh.K., Torpishchev F.Sh.; Declared 27.10.2009. Published. 20.06.2011. Bulletin No. 17. (In Russian).
2. Petrov V.P., Makridin N.I., Sokolova Yu.A., Yarmakovskii V.N. Tekhnologiya i materialovedenie poristykh zapolnitelei i legkikh betonov. Monografiya [Technology and materials porous aggregates and lightweight concrete. Monograph]. Moscow: “Paleotip”: RAACS. 2013. 332 p.
3. Simonov M.Z. Osnovy tekhnologii legkikh betonov [Technology basics of lightweight concrete]. Moscow: Stroyizdat. 1973. 583 p.
4. Orentlikher L.P. Betony na poristykh zapolnitelyakh v sbornykh zhelezobetonnykh konstruktsiyakh [Concrete with porous aggregates in precast concrete structures]. Moscow: Stroyizdat. 1983. 144 p.
5. Krasil’nikov K.G., Nikitina L.V., Skoblinskaya N.N. Fizikokhimiya sobstvennykh deformatsii tsementnogo kamnya [Physical chemistry of its own strain of cement paste]. Moscow: Stroyizdat. 1980. 252 p.
6. Akhverdov I.N. Osnovy fiziki betona [Fundamentals of physics concrete]. Moscow: Stroyizdat. 1981. 456 p.
7. Kosmatka S.H., Kerkhoff B. Design and Control of Concrete Mixtures. Guide to Application, Methods, and Materials. Ottawa, Cement Association of Canada, 2011, 411 p.
8. FIP Manual of Lightweight Aggregate Concrete. Third Edition. Glasgow and London. Surrey University Press. 2003. 255 p.
9. Yarmakovsky V.N., Pustovgar A.P. The scientific basis for the creation of a composite binders class, characterized of the low heat conductivity and low sorption activity of cement stone. Proceeding of XXIV R-S-P seminar. Theoretical Foundation of Civil Engineering (24RSP). Procedia Engineering. 2015. 111, pp. 864–870.
10. Kaushanskiy V.E. The use of man-made materials in the manufacture of cement. Proceedings of the International scientific-practical conference “Science and technology of silicate materials – present and future date.” MUCTR. D.I. Mendeleev. 14–17 oct. 2003, pp. 36–50. (In Russian).
11. Karpenko N.I., Yarmakovskiy V.N., Shkol’nik Ya.Sh. Status and prospects of the processed products of man-made structures in the construction industry. Ekologiya i promyshlennost’ Rossii. 2012. No. 10, pp. 50–54. (In Russian).
12. Butt Yu.M., Maier A.A., Marshal B.G. Hydration mineralogical components of blast furnace slag. In the book: Questions of slag. Proceedings of the Chelyabinsk “PromstroyNIIproekt”. 1960, pp. 418–446. (In Russian).
13. Gorshkov V.S., Aleksandrov S.E., Ivashchenko S.I., Gorshkova I.V. Kompleksnaya pererabotka i ispol’zovanie metallurgicheskikh shlakov v stroitel’stve [Complex processing and utilization of metallurgical slag in construction]. Moscow: Stroyizdat. 1985. 273 p.
14. Gemmerling G.V., Tsimermanis L.B. Shlakopemzobeton. [Shlakopemzobeton. Moscow: Stroyizdat. 1969. 135 p.
15. Botvinkin O.K. Fizicheskaya khimiya silikatov [Physical chemistry of silicates]. Moscow: Stroyizdat. 1955. 287 p.
16. Yarmakovskiy V.N On the method of calculation of reinforced concrete structures increased frost resistance. Proceedings NIIZhB “Improving the durability of concrete and reinforced concrete when exposed to aggressive environments”. Moscow: Gosstroi SSSR Stroyizdat. 1975. pp. 34–38. (In Russian).
17. Zaitsev Yu.V. Modelirovanie deformatsiy i prochnosti betona metodami mekhaniki razrusheniya [Simulation of deformation and strength of concrete methods of fracture mechanics]. Moscow: Stroyizdat. 1982. 196 p.
18. Karpenko N.I. Obshchie modeli mekhaniki zhelezobetona [General mechanics model of reinforced concrete]. Moscow: Stroyizdat. 1996. 208 p.
19. Patent RF 2421421. Modifikator betona i sposob ego polucheniya [Modifier concrete and its production method]. Yarmakovskiy V.N., Torpishchev Sh.K., Torpishchev F.Sh.; Declared 27.10.2009. Published. 20.06.2011. Bulletin No. 17. (In Russian).
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