AbstractAbout AuthorsReferences
Technical solutions, which make it possible to manufacture chamber kilns of periodical action for ceramic products burning meeting the complex of technological and energy-environmental requirements, are considered. It is shown that the manufacture of chamber kilns for small enterprises which produce from 5 to 15 million pieces of equivalent brick per year and especially use the method of compression molding is very actual one. It is possible to execute the reducing firing in gas-tight chamber kilns. The design of the chamber kiln with recirculation contours makes it possible, with the use of high-speed recuperative burners, to obtain the high uniformity of the temperature field on the surface of heated products and for the whole volume of kiln space as well as to reduce the fuel consumption by up to 40%
V.V. KURNOSOV1 , Candidate of Sciences (Physics and Mathematics) (This email address is being protected from spambots. You need JavaScript enabled to view it.),
A.A. DOROZhKIN2 , Engineer (This email address is being protected from spambots. You need JavaScript enabled to view it.),
N.N. KALININA2 , Engineer,
V.R. TIHONOVA1 , Engineer,
A.V. FILATOV1 , Master
A.A. DOROZhKIN2 , Engineer (This email address is being protected from spambots. You need JavaScript enabled to view it.),
N.N. KALININA2 , Engineer,
V.R. TIHONOVA1 , Engineer,
A.V. FILATOV1 , Master
1 OOO «KOMAS» (8A, Martovskaja Street, Aprelevka, Moscow Region, 143362, Russian Federation)
2 OOO NPP «Teploograzhdenie» (1, Parkovaja Street, Aprelevka, Moscow Region, 143360, Russian Federation)
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2. Shakhov I.I., Kurnosov V.V. Two-chamber furnace for firing ceramic products. Stroitel’nye Materialy [Construction Materials]. 2003. No. 2, p. 24. (In Russian).
3. Ashmarin G.D., Kurnosov V.V., Lastochkin V.G. Energy and resources saving technology of ceramic wall materials. Stroitel’nye Materialy [Construction Materials]. 2010. No. 4, pp. 24–27. (In Russian).
4. Ashmarin G.D., Lastochkin V.G., Sinyansky V.I., Ilyukhin V.V., Kurnosov V.V. Reduction of a cycle of thermal treatment in technology of ceramic brick compression moulding. Stroitel’nye Materialy [Construction Materials]. 2013. No. 4, pp. 43–44. (In Russian).
5. Grishin I.E., Gorshkov A.S., Gubin B.P. On increasing the energy efficiency of thermal units due to the prospects of the use of modern fire-resistant and heat-insulating materials. Novye ogneupory. 2007. No. 12, pp. 6–9. (In Russian).
6. Shakhov I.I., Dorozhkin A.A., Kalinina N.N., Kurnosov V.V. Construction linings of thermal and heating furnaces based fibrous refractory materials. Proceedings of the III International scientific-practical conference: Metallurgical heat engineering: history, current status and future. On the centenary of the birth of Glinkova M.A. 2006. (In Russian).
7. Nevgen P., Richardson D. Unique anchor design produces improved refractory performance (Vhi – Gmbh). The Refractories Engineer. 2003. p. 38.
8. Grechishnikov Ya.M., Belov M.L., Kurnosov V.V. Construction of a two-stage system with width modulation to control the temperature of the combustion furnace. Kuznechno-shtampovochnoe proizvodstvo. 1987. No. 10. (In Russian).
9. Dorokhina O.G., Kurnosov V.V., Levitskii I.A. Mathematical modeling of gas dynamics and heat transfer in the workspace precision heating furnace at various modes of burners. Sbornik nauchnykh trudov Sword. 2012. Vol. 10. (In Russian).
10. Spirin N.A., Lavrov V.V., Rybolovlev V.Yu., Krasnobaev A.V., Onorin O.P., Kosachenko I.E. Model’nye sistemy podderzhki prinyatiya reshenii v ASUTP domennoi plavki [Model decision support system in an automated blast furnace control system]. Ekaterinburg: UrFU. 2011. 462 p.
2. Shakhov I.I., Kurnosov V.V. Two-chamber furnace for firing ceramic products. Stroitel’nye Materialy [Construction Materials]. 2003. No. 2, p. 24. (In Russian).
3. Ashmarin G.D., Kurnosov V.V., Lastochkin V.G. Energy and resources saving technology of ceramic wall materials. Stroitel’nye Materialy [Construction Materials]. 2010. No. 4, pp. 24–27. (In Russian).
4. Ashmarin G.D., Lastochkin V.G., Sinyansky V.I., Ilyukhin V.V., Kurnosov V.V. Reduction of a cycle of thermal treatment in technology of ceramic brick compression moulding. Stroitel’nye Materialy [Construction Materials]. 2013. No. 4, pp. 43–44. (In Russian).
5. Grishin I.E., Gorshkov A.S., Gubin B.P. On increasing the energy efficiency of thermal units due to the prospects of the use of modern fire-resistant and heat-insulating materials. Novye ogneupory. 2007. No. 12, pp. 6–9. (In Russian).
6. Shakhov I.I., Dorozhkin A.A., Kalinina N.N., Kurnosov V.V. Construction linings of thermal and heating furnaces based fibrous refractory materials. Proceedings of the III International scientific-practical conference: Metallurgical heat engineering: history, current status and future. On the centenary of the birth of Glinkova M.A. 2006. (In Russian).
7. Nevgen P., Richardson D. Unique anchor design produces improved refractory performance (Vhi – Gmbh). The Refractories Engineer. 2003. p. 38.
8. Grechishnikov Ya.M., Belov M.L., Kurnosov V.V. Construction of a two-stage system with width modulation to control the temperature of the combustion furnace. Kuznechno-shtampovochnoe proizvodstvo. 1987. No. 10. (In Russian).
9. Dorokhina O.G., Kurnosov V.V., Levitskii I.A. Mathematical modeling of gas dynamics and heat transfer in the workspace precision heating furnace at various modes of burners. Sbornik nauchnykh trudov Sword. 2012. Vol. 10. (In Russian).
10. Spirin N.A., Lavrov V.V., Rybolovlev V.Yu., Krasnobaev A.V., Onorin O.P., Kosachenko I.E. Model’nye sistemy podderzhki prinyatiya reshenii v ASUTP domennoi plavki [Model decision support system in an automated blast furnace control system]. Ekaterinburg: UrFU. 2011. 462 p.
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