AbstractAbout AuthorsReferences
The technology of the modification of clayey raw material with multi-layer nano-tubes is proposed as an alternative to the modification of brick loams with plastic clays. The technique of their introduction in the composition of clay mass in the form of dispersions in surfactant solutions is considered. The micro-structure of an adobe and ceramic body in the presence of an optimal amount of a nano-modifier was studied. The practical application of the proposed technology makes it possible to abandon the development of several quarries by enterpris- es in favor of more technological modifying additives, reduce the load on public roads and improve the region ecology. Results of the industrial approbation of developed recommenda- tions when producing the ceramic whole brick are presented. The technical effect is in improving drying properties, reducing the time for adobe draying, improving the appearance and improving operational indicators of wall ceramic when using small amounts of modifying additives.
А.N. BOGDANOV, Candidate of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.),
L.A. ABDRAKHMANOVA, Doctor of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.),
V.G. KHOZIN, Doctor of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.)
L.A. ABDRAKHMANOVA, Doctor of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.),
V.G. KHOZIN, Doctor of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.)
Kazan State University of Architecture and Engineering (1, Zelenaya Street, Kazan, 420043, Russian Federation)
1. Patent RF No. 2462431. Nanomodifitsirovannaya kerami cheskaya massa [The nanomodified ceramic weight]. Gabidullin M.G., Mindubayev A.A., Huzin A.F., Gabidullin B.M. Declared 24.01.2011. Published 27.09.2012. Bulletin No. 27. (In Russian).
2. Yakovlev G.I., Pervushin G.N., Polyanskikh I.S., Cyrene I., Machulaytis P., Pudov I. A., Senkov S.A., Politayeva A.I., Gordina A.F., Shaybadullina A.V.Nanostrukturirovanie kompozitov v stroitel’nom materialovedenii: monografiya. [Nanostructuring composites in construction materials science: monography]. Izhevsk: Publishing house of IzhGTU. 2014. 196 p.
3. Yakovlev G.I., Ginchitskaya Yu.N., Kiziniyevich O., Kiziniyevich V., Gordina A.F. Influence of dispersions of multilayer carbon nano-tubes on physical-mechanical characteristics and structure of building ceramics. Stroitel’nye Materialy [Construction Materials]. 2016. No. 8, рр. 25–29. (In Russian).
4. Yakovlev G.I., Mikhaylov Yu.O., Ginchitskaya Yu.N., Kiziniyevich O., Taybakhtina P.A., Balobanova Yu.A. The construction ceramics modified by dispersions of multi-walled carbon nanotubes. Stroitel’nye Materialy [Construction Materials]. 2017. No. 1–2, pp. 10–13. (In Russian).
5. Bogdanov A.N. Modification of clay raw materials multi- functional additives for production of wall ceramics. Cand. Diss (Engineering). Kazan. 2014. 206 p. (In Russian).
6. Maciulaitis R., Keriene · Jadvyga R., Yakovlev G., Kizinievi O., Malai kiene · J., Kizinievi V. Investigation of the possibilities to modify the building ceramics by utilising MWCNTs. Construction and building materials. 2014. Vol. 73, pp. 153–162.
7. Pop E., Mann D., Wang Q., Goodson K., Dai H. Thermal conductance of an individual single-wall carbon nanotube above room temperature. NanoLetters. 2006. No. 6 (1), pp. 96–100. DOI: 10.1021/nl052145f.
8. Glebova N.V., Nechitaylov A.A. Functionalization of a surface of multiwall carbon nanotubes. Pisma v GTF. 2010. Vol. 36. Book 19, pp. 8–15. (In Russian).
9. Filatov S.A., Dolgih M.N., Kuchinsky G.S., Akhremkova G.S., Gunkevich A.A., Kumeysha N.A. Thermal methods of the analysis of carbon nanomaterials. The 6-th Minsk International Forum across Heat and Mass transfer. Minsk. 2008, pp. 5–10. (In Russian).
10. Glebova N.V., Nechitailov A.A., Kukushkina Yu.A., Sokolov V.V. Research of thermal oxidation of carbon nanomaterials. Pisma v GTF. 2011. Vol. 37. Iss. 9, pp. 97–104. (In Russian).
11. Yu H., Lu C., Xi T., Luo L., Ning J., Xiang C. Thermal decomposition if the carbon nanotube/SiO2 precursor powders. Journal of Thermal Analysis and Colorimetry. 2005. Vol. 82, pp. 97–101.
12. Blagoveshchenskii Yu.V., Van K.V., Volodin A.A., Kiiko V.M., Kolchin A.A., Novokhatskaya N.I., Tarasov B.P., Tolstun A.N. Receiving and structure of composites with carbon nanotubes and ceramic matrixes. Komposity i nanostructury. 2010. No. 10, pp. 30–39. (In Russian)
2. Yakovlev G.I., Pervushin G.N., Polyanskikh I.S., Cyrene I., Machulaytis P., Pudov I. A., Senkov S.A., Politayeva A.I., Gordina A.F., Shaybadullina A.V.Nanostrukturirovanie kompozitov v stroitel’nom materialovedenii: monografiya. [Nanostructuring composites in construction materials science: monography]. Izhevsk: Publishing house of IzhGTU. 2014. 196 p.
3. Yakovlev G.I., Ginchitskaya Yu.N., Kiziniyevich O., Kiziniyevich V., Gordina A.F. Influence of dispersions of multilayer carbon nano-tubes on physical-mechanical characteristics and structure of building ceramics. Stroitel’nye Materialy [Construction Materials]. 2016. No. 8, рр. 25–29. (In Russian).
4. Yakovlev G.I., Mikhaylov Yu.O., Ginchitskaya Yu.N., Kiziniyevich O., Taybakhtina P.A., Balobanova Yu.A. The construction ceramics modified by dispersions of multi-walled carbon nanotubes. Stroitel’nye Materialy [Construction Materials]. 2017. No. 1–2, pp. 10–13. (In Russian).
5. Bogdanov A.N. Modification of clay raw materials multi- functional additives for production of wall ceramics. Cand. Diss (Engineering). Kazan. 2014. 206 p. (In Russian).
6. Maciulaitis R., Keriene · Jadvyga R., Yakovlev G., Kizinievi O., Malai kiene · J., Kizinievi V. Investigation of the possibilities to modify the building ceramics by utilising MWCNTs. Construction and building materials. 2014. Vol. 73, pp. 153–162.
7. Pop E., Mann D., Wang Q., Goodson K., Dai H. Thermal conductance of an individual single-wall carbon nanotube above room temperature. NanoLetters. 2006. No. 6 (1), pp. 96–100. DOI: 10.1021/nl052145f.
8. Glebova N.V., Nechitaylov A.A. Functionalization of a surface of multiwall carbon nanotubes. Pisma v GTF. 2010. Vol. 36. Book 19, pp. 8–15. (In Russian).
9. Filatov S.A., Dolgih M.N., Kuchinsky G.S., Akhremkova G.S., Gunkevich A.A., Kumeysha N.A. Thermal methods of the analysis of carbon nanomaterials. The 6-th Minsk International Forum across Heat and Mass transfer. Minsk. 2008, pp. 5–10. (In Russian).
10. Glebova N.V., Nechitailov A.A., Kukushkina Yu.A., Sokolov V.V. Research of thermal oxidation of carbon nanomaterials. Pisma v GTF. 2011. Vol. 37. Iss. 9, pp. 97–104. (In Russian).
11. Yu H., Lu C., Xi T., Luo L., Ning J., Xiang C. Thermal decomposition if the carbon nanotube/SiO2 precursor powders. Journal of Thermal Analysis and Colorimetry. 2005. Vol. 82, pp. 97–101.
12. Blagoveshchenskii Yu.V., Van K.V., Volodin A.A., Kiiko V.M., Kolchin A.A., Novokhatskaya N.I., Tarasov B.P., Tolstun A.N. Receiving and structure of composites with carbon nanotubes and ceramic matrixes. Komposity i nanostructury. 2010. No. 10, pp. 30–39. (In Russian)
For citation: Bogdanov А.N., Abdrakhmanova L.A., Khozin V.G. Modification of brick loams with multi-layer carbon nano-tubes for production of wall ceramics. Stroitel’nye Materialy [Construction Materials]. 2017. No. 9, pp. 14–17. DOI: https://doi.org/10.31659/0585-430X-2017-752-9-14-17. (In Russian).