KnE Engineering
ISSN: 2518-6841
The latest conference proceedings on all fields of engineering.
Mathematical Model of Heat Exchange of a Plasma Furnace
Published date: Jul 17 2018
Journal Title: KnE Engineering
Issue title: VII All-Russian Scientific and Practical Conference of Students, Graduate Students and Young Scientists (TIM'2018)
Pages: 144–153
Authors:
Abstract:
The principle of operation of the periodic action plasma furnace and options for describing the heat-and-chemical processes occurring in such furnaces are considered. There are given equations of heat transfer by radiation and convection, features of the thermal interaction of plasma with the solid particles surface, the influence of thermophysical properties and composition of particles on the efficiency of the furnace operation, as well as the possible chemistry of reactions to the parameters of plasma heating.
Keywords: plasma furnaces, thermophysical processes, radiation, convection, plasma heating chemistry
References:
[1] Telegin, A. S., Shvydkii, V. S., and Yaroshenko, Yu. G. (2002). Heat and Mass Transfer: Textbook for Universities, p. 455. Moscow: IKTs ‘Akademkniga’.
[2] Berezin, Yu. A. and Vshivkov, V. A. (1980). Particle Method in the Dynamics of Rarefied Plasma, p. 95. Novosibirsk: Science.
[3] Berezin, Yu. A. and Vshivkov, V. A. (1985). Numerical Models of Plasma and Reconnection Processes, p. 128. Moscow: Science.
[4] Dnestrovsky, Yu. N. and Kostomarov, D. P. (1982). Mathematical Modeling of Plasma, p. 336. Moscow: Science.
[5] Badsel, C. and Leng, A. (1989). Plasma Physics and Numerical Simulation: Translation from English, p. 452. Moscow: Energoatomizdat.
[6] Oks, E. A. (1989). Spectroscopy of a Plasma with Quasimono-quasimonochromatic Electric Fields: Translation from English, p. 320. Moscow: Energoatomizdat.
[7] Shvydkiy, V. S., Ladigichev, M. G., and Shavrin, V. S. (2005). Mathematical Methods of Thermophysics: A Textbook for High Schools, p. 232. Moscow: Teplotehnik.
[8] Barvinok, V. A. (2005). Plasma in Technology, Reliability, Resource, p. 456. Moscow: Science and Technology.
[9] Kudinov, V. V. and Bobrov, G. V. (1992). Coating by Spraying. Theory, Technology and Equipment—Textbook for high schools, p. 432. Moscow: Metallurgy.
[10] Dokukina, I. A. (2011). Investigation of the structure and properties thermal protection plasma coatings. Problems of Mechanical Engineering and Automation, no. 3, pp. 91–96.
[11] Dokukina, I. A. (2009). Theoretical studies of the formation of mesostructuredordered cluster structures in plasma coatings. Problems of Mechanical Engineering and Automation, no. 4, pp. 106–112.
[12] Barvinok, V. A., Bogdanovich, V. I., Dokukina, I. A., et al. (2008). Physical and mathematical modeling of the dynamics of the motion of dispersed particles in a plasma jet. Izvestiya Samara Scientific Center, no. 3, pp. 70–76.
[13] Ivanov, E. M. (1983). Engineering Calculation of Thermophysical Processes in Plasma Deposition, Saratov (ed.), p. 138. Saratov University.
[14] Lykov, A. V. (1967). Theory of Thermal Conductivity, p. 600. Moscow: High School.
[15] Barvinok, V. A., Bogdanovich, V. I., and Dokukina, I. A. (1998). Mathematical Modeling and Physics of the Processes of Depositing Plasma Coatings from Composite Clad Powders, p. 96. Moscow: International Center of STI.
[16] Kartashev, E. M. (2001). Analytic Methods in the Theory of Thermal Conductivity of Solids, p. 530. Moscow: High School.
[17] Fainer, N. I. (2015). Phase composition of thin silicon carbonitride films by means of plazma endensive chemical vapor deposition using organosilicon compounds. Journal of Structural Chemistry, vol. 56, pp. 163–174.
[18] Fleischmann H. H., Ashby, D. E. T. F., and Larson, A.V. (1965). Errors in the use of mass analyzers in the plasma physics. Nuclear Fusion, vol. 5.
[19] Lybacki, W. (2004). Induction-plasma melting of cast iron. Czechoslovak Journal of Physics, pp. 1022–1026.
[20] Tsvetkov, Yu. V., Nikolaev, A.V., and Samokhin A.V. (2013). Plasma processes in metallurgy and inorganic materials technology. Automatic Welding, no. 10, pp. 112– 118.