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The Comparison of Two Calculation Methods of Billets Heating in Furnaces with the Help of Zone and FVM Methods

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:251–258

DOI: 10.18502/keg.v3i5.2677

Authors:
Abstract:

The comparison of two modelling methods for radiation heat exchange – finite volume and zonal methods – has been provided. The mathematical model of heating concast bars ring furnace has been created. Modelling of different heat modes of this furnace has been completed. In the result of modelling, it is shown that these methods demonstrate similar accuracy of obtained temperature values (not exceeding 50∘C). The calculation time of FVM method is greater than zonal method to 13%, because recalculations of absorption coefficients by EWBM method is needed.


Keywords: radiation transfer, mathematical modeling, zonal method, discrete transfer zonal method

References:

[1] Modest, M. F. (2003). Radiative Heat Transfer (second edition). New York: Academic Press.


[2] Lockwood, F. C. and Shah, N. G. (1981). A new radiation solution method for incorporation in general combustion prediction procedures, in Eighteenth Symposium on Combustion, pp. 1405–1412. Pittsburgh: The Combustion Institute.


[3] Lisienko, V. G. (2008). Improvement and Efficiency Energy Technologies and Industries (Integrated Energy-technological Analysis: Theory and Practice), 608с. M.: Teplotekhnik.


[4] Lisienko, V. G., Zhuravlev, A. Yu., and Kataev, B. I. (1973). Analysis of the local characteristics of external high temperature heat exchange in flame furnaces. Izvestiya Vuzov. Iron and Steel, no. 6, pp. 131–135.


[5] Malikov, G., Lisienko, V., Viskanta, R., et al. (2014). A new method for direct exchange area calculation in zonal method of radiant heat transfer modeling in combustion furnaces, in IMECE2014-36983, pp. 1–6.


[6] Toporov, V. A., Gubin, Yu., Shipunov, M. A., et al. Patent for useful model RU 128301 U1 Device bottom annular heating furnace (priority of 12.11.2012).

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