AbstractAbout AuthorsReferences
This work is a continuation of the cycle of articles under the general title “Heat transfer in enclosing structures of a blast furnace”. Typical multilayered enclosing structures of the blast furnace are considered in the part 1 [1]. The description of layers which are a part of these designs is resulted. The main attention is paid to the lining layer. The process of iron smelting and operating temperatures in the characteristic layers of the internal environment of the blast furnace is briefly described. On the basis of the theory of A.V. Lykov, initial equations describing the interconnected heat transfer and mass in the solid body applying to the set task, an adequate description of the processes with the purpose of further rational design of the multilayered enclosing structure of the blast furnace, are analyzed. Apriori, from the mathematical point of view the enclosing structure is considered as an unbounded plate. Boundary problems of the heat transfer in separate layers of the structure with different boundary conditions are considered in the part 2, their solutions, which are basic when developing the mathematical model of the non-stationary process of the heat transfer in the multilayered enclosing structure, are presented.
A.M. IBRAGIMOV, Doctor of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.)
A.V. LIPENINA, Student, (This email address is being protected from spambots. You need JavaScript enabled to view it.)
L.Yu. GNEDINA, Candidate of Sciences (Engineering)
A.V. LIPENINA, Student, (This email address is being protected from spambots. You need JavaScript enabled to view it.)
L.Yu. GNEDINA, Candidate of Sciences (Engineering)
National Research Moscow State University of Civil Engineering (26, Yaroslavskoye Highway, 129337, Moscow, Russian Federation)
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5. Fedosov S.V., Kisel’nikov V.N., Shertaev T.U. Primenenie metodov teorii teploprovodnosti dlya modelirovaniya protsessov konvektivnoy sushki [Application of the methods of the theory of thermal conductivity for modeling the processes of convective drying]. Alma-Ata: Gylym. 1992. 168 p.
6. Fedosov S.V., Gnedina L.Yu. Non-stationary heat transfer in a multilayered enclosing structure. Problems of building thermophysics of microclimate and energy saving systems in buildings: Coll. reports of the IV scientific-practical conference. 27–29 April 1999. Mosscow. 343–348 p.
7. Chizil’skiy E. Ventilated exterior wall constructions. Zhilishchnoe Stroitel’stvo. 1996. No. 10, pp. 25–27. (In Russian).
8. Shmelev A.L. Fedosov S.V., Zaytsev V.A., Sokol’skiy A.I., Kisel’nikov V.N. Modelirovanie nestatsionarnogo teploperenosa v reaktore gidroliza tsiansoderzhashchikh polimerov [Modeling of non-stationary heat transfer in the reactor of hydrolysis of cyanide-containing polymers]. Ivanovo Chemical Technology Institute. 1988. Dep. in the NIITEKhIM. N1076-XII88.
9. Shmelev A.L. A continuous method for producing watersoluble polymers based on polyacrylonitrile with a high content of the basic substance. Cand. Diss. (Engineering). Ivanovo. 1998. (In Russian).
10. Lykov A.V., Mikhaylov Yu.A. Teoriya perenosa energii i veshchestva [Theory of energy and matter transfer]. Minsk: AN BSSR Publishing. 1959. 330 p.
11. Fedosov S.V., Ibragimov A.M., Gnedina L.YU., Gushchin A.V. Mathematical model of non-stationary heat transfer in a multilayered enclosing structure. Reports of the XII Russian-Polish seminar “Theoretical Foundations of Construction”. Warsaw: 2003, pp. 253–261. (In Russian).
2. Fedosov S.V. Analytical description of heat and moisture transfer during drying of dispersed materials in the presence of thermal diffusion and internal evaporation of moisture. Zhurnal prikladnoy khimii. 1986. Vol. 59. No. 3, pp. 2033–2038. (In Russian).
3. Fedosov S.V., Kiselnikov V.N. Heat transfer in a spherical particle with convective drying in a suspended state. Izvestiya vuzov. Khimiya i khimicheskaya tekhnologiya. 1985. Vol. 28. No. 2, pp. 14–15. (In Russian).
4. Fedosov S.V., Zaytsev V.A., SHmelev A.L. Calculation of temperature fields in a cylindrical reactor with a nonuniformly distributed heat source. State and prospects of development of electro technology. Abstracts of the All-Russian Scientific and Technical Conference. Ivanovo. 1987. 28 p.
5. Fedosov S.V., Kisel’nikov V.N., Shertaev T.U. Primenenie metodov teorii teploprovodnosti dlya modelirovaniya protsessov konvektivnoy sushki [Application of the methods of the theory of thermal conductivity for modeling the processes of convective drying]. Alma-Ata: Gylym. 1992. 168 p.
6. Fedosov S.V., Gnedina L.Yu. Non-stationary heat transfer in a multilayered enclosing structure. Problems of building thermophysics of microclimate and energy saving systems in buildings: Coll. reports of the IV scientific-practical conference. 27–29 April 1999. Mosscow. 343–348 p.
7. Chizil’skiy E. Ventilated exterior wall constructions. Zhilishchnoe Stroitel’stvo. 1996. No. 10, pp. 25–27. (In Russian).
8. Shmelev A.L. Fedosov S.V., Zaytsev V.A., Sokol’skiy A.I., Kisel’nikov V.N. Modelirovanie nestatsionarnogo teploperenosa v reaktore gidroliza tsiansoderzhashchikh polimerov [Modeling of non-stationary heat transfer in the reactor of hydrolysis of cyanide-containing polymers]. Ivanovo Chemical Technology Institute. 1988. Dep. in the NIITEKhIM. N1076-XII88.
9. Shmelev A.L. A continuous method for producing watersoluble polymers based on polyacrylonitrile with a high content of the basic substance. Cand. Diss. (Engineering). Ivanovo. 1998. (In Russian).
10. Lykov A.V., Mikhaylov Yu.A. Teoriya perenosa energii i veshchestva [Theory of energy and matter transfer]. Minsk: AN BSSR Publishing. 1959. 330 p.
11. Fedosov S.V., Ibragimov A.M., Gnedina L.YU., Gushchin A.V. Mathematical model of non-stationary heat transfer in a multilayered enclosing structure. Reports of the XII Russian-Polish seminar “Theoretical Foundations of Construction”. Warsaw: 2003, pp. 253–261. (In Russian).
For citation: Ibragimov A.M., Lipenina A.V., Gnedina L.Yu. Design of the blast furnace wall structure made of efficient materials. Part 2. Solution of boundary problems of heat transfer. Stroitel’nye Materialy [Construction Materials]. 2018. No. 5, pp. 73–76. DOI: https://doi.org/doi.org/10.31659/0585-430X-2018-759-5-73-76 (In Russian).