AbstractAbout AuthorsReferences
Main results of the study of influence of dispersions of multilayer carbon nano-tubes (MCNT) Masterbatch CW 2-45 on the physical-mechanical characteristics and structure of building ceramics are presented. Dispersions obtained at the high-speed homogenizer and treated by ultrasound were used in studies. It is proved that the introduction of these dispersions in the charge for manufacturing the building ceramics contributes to improving the homogeneity of ceramic matrix structure and reducing its porosity. The change in the structure of a ceramic crock leads to improving mechanical indicators of ceramic samples before and after burning. It is established that introducing the optimal percent of MCNT in the amount of 0.001% of the mass formed makes it possible to modify the ceramic matrix, improving its physical-mechanical characteristics by 28–32%.
G.I. YAKOVLEV1 , Doctor of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.),
Yu.N. GINCHITSKAYA1 , Master;
O. KIZINIEVICH2 , Doctor-Engineer (This email address is being protected from spambots. You need JavaScript enabled to view it.),
V. KIZINIEVICH2 , Doctor-Engineer;
A.F. GORDINA1 , Master
1Kalashnikov Izhevsk State Technical University (7, Studencheskaya Street, Izhevsk, 426069, Russian Federation)
2 Vilnius Gediminas Technical University (11, Saulétekio al., LT–10223, Vilnius, Lithuania)
Yu.N. GINCHITSKAYA1 , Master;
O. KIZINIEVICH2 , Doctor-Engineer (This email address is being protected from spambots. You need JavaScript enabled to view it.),
V. KIZINIEVICH2 , Doctor-Engineer;
A.F. GORDINA1 , Master
1Kalashnikov Izhevsk State Technical University (7, Studencheskaya Street, Izhevsk, 426069, Russian Federation)
2 Vilnius Gediminas Technical University (11, Saulétekio al., LT–10223, Vilnius, Lithuania)
1. Samal S., Bal S. Carbon Nanotube Reinforced Ceramic Matrix Composites – A Review. Journal of Minerals & Materials Characterization & Engineering. 2008. Vol. 7, pp. 355–370.
2. Yang F.Y., Zhang X.H., Han J.C., Du S.Y. Processing and mechanical properties of short carbon fibers toughened zirconium diboride-based ceramics. Materials & Design. 2008. Vol. 29, pp. 1817–1820.
3. Corral E.L., Loehman R.E. Ultra-High-Temperature Ceramic Coatings for Oxidation Protection of CarbonCarbon Composites. Journal of the American Ceramic Society. 2008. Vol. 91, pp. 1495–1502.
4. Inam F., Yan H., Reece M.J., Peijs T. Dimethylformamide: an effective dispersant for making ceramic–carbon nanotube composites. Nanotechnology. 2008. Vol. 19, pp. 355–370.
5. Poyato R., Vasiliev A.L., Padture N.P., Tanaka H., Nishimura T. Aqueous colloidal processing of single-wall carbon nanotubes and their composites with ceramics. Nanotechnology. 2006. Vol. 17, pp. 1770–1777.
6. Belmonte M., Vallés C., Maser W.K., Benito A.M., Martinez M.T., Miranzo P., Osendi M.I. Processing route to disentangle multi-walled carbon nanotube towards ceramic composite. Journal of Nanoscience and Nanotechnology. 2009. No. 9, pp. 6164–6170. Шайбадуллина А.В., Гордина А.Ф. Наномодифицирование керамических материалов строительного назначения // Строительные материалы. 2013. № 4. С. 62–64.
7. Kamalakaran R., Lupo F., Grobert N., Lozano-Castello D., Jin-Philipp N.Y., Ruhle M. In-situ formation of carbon nanotubes in an alumina-nanotube composite by spray pyrolysis. Carbon. 2003. Vol. 41, pp. 2737– 2741.
8. Dillon F.C., Moghal J., Koos A., Lozano J.G., Miranda L., Porwal H., Reece M.J., Grobert N. Ceramic composites from mesoporous silica coated multi-wall carbon nanotubes. Microporous and Mesoporous Materials. 2015. No. 217, pp. 159–166.
9. Qing Y., Zhou W., Huang Sh., Huang Zh., Luo F., Zhu D. Microwave absorbing ceramic coatings with multi-walled carbon nanotubes and ceramic powder by polymer pyrolysis route. Composites Science and Technology. 2013. No. 89, pp. 10–14.
10. Dassios K.G., Bonnefont G., Fantozzi G., Matikas T.E. Novel highly scalable carbon nanotube-strengthened ceramics by high shear compaction and spark plasma sintering. Journal of the European Ceramic Society. 2015. No. 35, pp. 2599–2606.
11. Hvizdos P., Puchy V., Duszova A., Dusza J., Balazsi Cs.. Tribological and electrical properties of ceramic matrix composites with carbon nanotubes. Ceramics International. 2012. Vol. 38, pp. 5669–5676.
12. Inam F., Yan H., Peijs T., Reece M.J. The sintering and grain growth behaviour of ceramic–carbon nanotube nanocomposites. Composites Science and Technology. 2010. Vol. 70, pp. 947–952. 13. Яковлев Г.И., Полянских И.С., Мачюлайтис Р., Керене Я., Малайшкене Ю., Кизиниевич О.,
13. Yakovlev G.i., Polyanskikh (Maeva) M.s., Machyulaytis R., Kerene Ya., Malayshkene C.yu., Kizinevich O., Shaybadullina A.v., Gordina A.f. Nanomodofication of ceramic materials for construction purposes. Stroitel’nye Materialy [Construction Materials]. 2013. No. 4, pp. 62– 64. (In Russian).
14. Яковлев Г.И., Полянских И.С., Шайбадуллина А.В., Гордина А.Ф., Бочкарева Т.В., Зайцева Е.А. Перспективы наномодифицирования керамических материалов строительного назначения // Интеллектуальные системы в производстве. 2013. № 1. С. 189–192. 14. Yakovlev G.I., Poljanskih I.S., Shajbadullina A.V., Gordina A.F., Bochkareva T.V., Zajtseva E.A. Prospects of nano-modification of ceramic materials for building purposes. Intellektual’nye sistemy v proizvodstve. 2013. No. 1, pp. 189–192. (In Russian).
15. Михеев В.И. Рентгенометрический определитель минералов. М.: Гос. научн.-техн. изд-во литературы по геологии и охране недр, 1957. 870 с. 15. Miheev V.I. Rentgenometricheskij opredelitel’ mineralov [Radiometric determiner of minerals]. Moscow: Gosudarstvennoe nauchno-technicheskoe izdatel’stvo literatury po geologii I ohrane nedr. 1957. 870 p.
2. Yang F.Y., Zhang X.H., Han J.C., Du S.Y. Processing and mechanical properties of short carbon fibers toughened zirconium diboride-based ceramics. Materials & Design. 2008. Vol. 29, pp. 1817–1820.
3. Corral E.L., Loehman R.E. Ultra-High-Temperature Ceramic Coatings for Oxidation Protection of CarbonCarbon Composites. Journal of the American Ceramic Society. 2008. Vol. 91, pp. 1495–1502.
4. Inam F., Yan H., Reece M.J., Peijs T. Dimethylformamide: an effective dispersant for making ceramic–carbon nanotube composites. Nanotechnology. 2008. Vol. 19, pp. 355–370.
5. Poyato R., Vasiliev A.L., Padture N.P., Tanaka H., Nishimura T. Aqueous colloidal processing of single-wall carbon nanotubes and their composites with ceramics. Nanotechnology. 2006. Vol. 17, pp. 1770–1777.
6. Belmonte M., Vallés C., Maser W.K., Benito A.M., Martinez M.T., Miranzo P., Osendi M.I. Processing route to disentangle multi-walled carbon nanotube towards ceramic composite. Journal of Nanoscience and Nanotechnology. 2009. No. 9, pp. 6164–6170. Шайбадуллина А.В., Гордина А.Ф. Наномодифицирование керамических материалов строительного назначения // Строительные материалы. 2013. № 4. С. 62–64.
7. Kamalakaran R., Lupo F., Grobert N., Lozano-Castello D., Jin-Philipp N.Y., Ruhle M. In-situ formation of carbon nanotubes in an alumina-nanotube composite by spray pyrolysis. Carbon. 2003. Vol. 41, pp. 2737– 2741.
8. Dillon F.C., Moghal J., Koos A., Lozano J.G., Miranda L., Porwal H., Reece M.J., Grobert N. Ceramic composites from mesoporous silica coated multi-wall carbon nanotubes. Microporous and Mesoporous Materials. 2015. No. 217, pp. 159–166.
9. Qing Y., Zhou W., Huang Sh., Huang Zh., Luo F., Zhu D. Microwave absorbing ceramic coatings with multi-walled carbon nanotubes and ceramic powder by polymer pyrolysis route. Composites Science and Technology. 2013. No. 89, pp. 10–14.
10. Dassios K.G., Bonnefont G., Fantozzi G., Matikas T.E. Novel highly scalable carbon nanotube-strengthened ceramics by high shear compaction and spark plasma sintering. Journal of the European Ceramic Society. 2015. No. 35, pp. 2599–2606.
11. Hvizdos P., Puchy V., Duszova A., Dusza J., Balazsi Cs.. Tribological and electrical properties of ceramic matrix composites with carbon nanotubes. Ceramics International. 2012. Vol. 38, pp. 5669–5676.
12. Inam F., Yan H., Peijs T., Reece M.J. The sintering and grain growth behaviour of ceramic–carbon nanotube nanocomposites. Composites Science and Technology. 2010. Vol. 70, pp. 947–952. 13. Яковлев Г.И., Полянских И.С., Мачюлайтис Р., Керене Я., Малайшкене Ю., Кизиниевич О.,
13. Yakovlev G.i., Polyanskikh (Maeva) M.s., Machyulaytis R., Kerene Ya., Malayshkene C.yu., Kizinevich O., Shaybadullina A.v., Gordina A.f. Nanomodofication of ceramic materials for construction purposes. Stroitel’nye Materialy [Construction Materials]. 2013. No. 4, pp. 62– 64. (In Russian).
14. Яковлев Г.И., Полянских И.С., Шайбадуллина А.В., Гордина А.Ф., Бочкарева Т.В., Зайцева Е.А. Перспективы наномодифицирования керамических материалов строительного назначения // Интеллектуальные системы в производстве. 2013. № 1. С. 189–192. 14. Yakovlev G.I., Poljanskih I.S., Shajbadullina A.V., Gordina A.F., Bochkareva T.V., Zajtseva E.A. Prospects of nano-modification of ceramic materials for building purposes. Intellektual’nye sistemy v proizvodstve. 2013. No. 1, pp. 189–192. (In Russian).
15. Михеев В.И. Рентгенометрический определитель минералов. М.: Гос. научн.-техн. изд-во литературы по геологии и охране недр, 1957. 870 с. 15. Miheev V.I. Rentgenometricheskij opredelitel’ mineralov [Radiometric determiner of minerals]. Moscow: Gosudarstvennoe nauchno-technicheskoe izdatel’stvo literatury po geologii I ohrane nedr. 1957. 870 p.
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