This paper is devoted to the simulation of 3D transient radiation and conduction heat transfer occurring inside thin glass sheets undergoing high temperature processing. The glass is considered as an absorbing, emitting, and nonscattering medium. The zonal method is used to establish the governing radiation transfer model. Direct exchange areas are calculated by the flux planes approximation. The thin layer approximation (TLA) is then introduced for increasing CPU efficiency. Three different numerical integration schemes made possible by the TLA are presented. Comparisons are made, with calculations performed using the finite volume method (FVM). The transient coupled energy equation is solved by a full implicit control volume method using the incomplete Cholesky conjugate gradient method. The heat transfer analysis of a glass sheet residing inside a hot rectangular enclosure is studied. Results obtained by the zonal method, with or without the TLA, are in close agreement with those obtained by the FVM. CPU requirements for radiative heat transfer analysis of the zonal method with TLA are, depending on the numerical integration scheme used, between 8 and 23 times smaller than those of the zonal method without TLA. The difference between the results of the different models never exceeds 4%. The zonal method with the TLA offered significant improvements in CPU time when compared with the original zonal method with similar or acceptable accuracy.
Skip Nav Destination
e-mail: georges.el_hitti@mines-paristech.fr
Article navigation
Research Papers
Transient Radiation and Conduction Heat Transfer in Glass Sheets by the Thin Layer Approximation
Georges El Hitti,
e-mail: georges.el_hitti@mines-paristech.fr
Georges El Hitti
Mines ParisTech
, Center for Energy and Process Studies (CEP), CNRS FRE 2861, 60 Boulevard Saint-Michel, F-75272 Paris Cedex 06, France
Search for other works by this author on:
Maroun Nemer,
Maroun Nemer
Mines ParisTech
, Center for Energy and Process Studies (CEP), CNRS FRE 2861, 60 Boulevard Saint-Michel, F-75272 Paris Cedex 06, France
Search for other works by this author on:
Khalil El Khoury
Khalil El Khoury
Mines ParisTech
, Center for Energy and Process Studies (CEP), CNRS FRE 2861, 60 Boulevard Saint-Michel, F-75272 Paris Cedex 06, France
Search for other works by this author on:
Georges El Hitti
Mines ParisTech
, Center for Energy and Process Studies (CEP), CNRS FRE 2861, 60 Boulevard Saint-Michel, F-75272 Paris Cedex 06, Francee-mail: georges.el_hitti@mines-paristech.fr
Maroun Nemer
Mines ParisTech
, Center for Energy and Process Studies (CEP), CNRS FRE 2861, 60 Boulevard Saint-Michel, F-75272 Paris Cedex 06, France
Khalil El Khoury
Mines ParisTech
, Center for Energy and Process Studies (CEP), CNRS FRE 2861, 60 Boulevard Saint-Michel, F-75272 Paris Cedex 06, FranceJ. Heat Transfer. Feb 2010, 132(2): 023506 (8 pages)
Published Online: December 3, 2009
Article history
Received:
October 31, 2008
Revised:
March 20, 2009
Online:
December 3, 2009
Published:
December 3, 2009
Citation
El Hitti, G., Nemer, M., and El Khoury, K. (December 3, 2009). "Transient Radiation and Conduction Heat Transfer in Glass Sheets by the Thin Layer Approximation." ASME. J. Heat Transfer. February 2010; 132(2): 023506. https://doi.org/10.1115/1.4000228
Download citation file:
Get Email Alerts
Cited By
Related Articles
Modeling of Advanced Melting Zone for Manufacturing of Optical Fibers
J. Manuf. Sci. Eng (May,2004)
A Numerical Simulation of Combined Radiation and Natural Convection in a Differential Heated Cubic Cavity
J. Heat Transfer (February,2010)
Effects of Radiative Transfer Modeling on Transient Temperature Distribution in Semitransparent Glass Rod
J. Heat Transfer (August,2003)
Numerical Analysis of Depollution of Smoke Produced by Household Wastes Incineration
J. Heat Transfer (April,2012)
Related Proceedings Papers
Related Chapters
Short-Pulse Collimated Radiation in a Participating Medium Bounded by Diffusely Reflecting Boundaries
International Conference on Mechanical and Electrical Technology, 3rd, (ICMET-China 2011), Volumes 1–3
Radiation
Thermal Management of Microelectronic Equipment
Radiation
Thermal Management of Microelectronic Equipment, Second Edition