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Coupling of a discrete ordinate 3-D radiant heat transfer model with the PHOENICS fluid mechanics software; Couplage d`un modele radiatif tridimensionnel aux ordonnees discretes au logiciel de mecanique des fluides phoenics

Abstract

Radiant heat transfer is the main solution retained in many iron and steel metallurgy installations (re-heating and annealing furnaces etc..). Today, it has become important to dispose of performing radiant heat transfer models in heat transfer and fluid mechanics simulation softwares, and well adapted to multidimensional industrial problems. This work presents the discrete ordinate radiant heat transfer model developed at the IRSID (the French institute of research in iron and steel metallurgy) and coupled with the PHOENICS heat transfer-fluid mechanics software. Three modeling approaches are presented concerning the radiative properties of gases (H{sub 2}O-CO{sub 2}). A ``weighted grey gases sum`` model gives satisfactory results for several 1-D validation cases. (J.S.) 20 refs.
Authors:
Muller, J [1] 
  1. IRSID, Institut de Recherches Siderurgie, 57 - Maizieres-les-Metz (France)
Publication Date:
Dec 31, 1996
Product Type:
Conference
Report Number:
ETDE-FR-99703312; CONF-9602163-
Reference Number:
SCA: 420400; 990200; PA: FRC-98:004830; EDB-99:046714; SN: 98002014926
Resource Relation:
Conference: Workshop on calculation codes for radiant heat transfers, Journee d`etudes sur les codes de calcul de rayonnement thermique, France (France), 14 Feb 1996; Other Information: PBD: 1996; Related Information: Is Part Of Calculation codes for radiant heat transfers; PB: 158 p.; Les codes de calcul de rayonnement thermique
Subject:
42 ENGINEERING NOT INCLUDED IN OTHER CATEGORIES; 99 MATHEMATICS, COMPUTERS, INFORMATION SCIENCE, MANAGEMENT, LAW, MISCELLANEOUS; RADIANT HEAT TRANSFER; METAL INDUSTRY; COMPUTERIZED SIMULATION; DISCRETE ORDINATE METHOD; FLUID MECHANICS; P CODES; FURNACES; FINITE ELEMENT METHOD; HEAT FLUX; COMBUSTION PRODUCTS; EMISSIVITY; ABSORPTION SPECTRA
OSTI ID:
333944
Research Organizations:
Societe Francaise des Thermiciens, 75 - Paris (France)
Country of Origin:
France
Language:
French
Other Identifying Numbers:
Other: ON: DE99703312; TRN: FR9804830
Availability:
OSTI as DE99703312
Submitting Site:
FR
Size:
pp. 99-112
Announcement Date:

Citation Formats

Muller, J. Coupling of a discrete ordinate 3-D radiant heat transfer model with the PHOENICS fluid mechanics software; Couplage d`un modele radiatif tridimensionnel aux ordonnees discretes au logiciel de mecanique des fluides phoenics. France: N. p., 1996. Web.
Muller, J. Coupling of a discrete ordinate 3-D radiant heat transfer model with the PHOENICS fluid mechanics software; Couplage d`un modele radiatif tridimensionnel aux ordonnees discretes au logiciel de mecanique des fluides phoenics. France.
Muller, J. 1996. "Coupling of a discrete ordinate 3-D radiant heat transfer model with the PHOENICS fluid mechanics software; Couplage d`un modele radiatif tridimensionnel aux ordonnees discretes au logiciel de mecanique des fluides phoenics." France.
@misc{etde_333944,
title = {Coupling of a discrete ordinate 3-D radiant heat transfer model with the PHOENICS fluid mechanics software; Couplage d`un modele radiatif tridimensionnel aux ordonnees discretes au logiciel de mecanique des fluides phoenics}
author = {Muller, J}
abstractNote = {Radiant heat transfer is the main solution retained in many iron and steel metallurgy installations (re-heating and annealing furnaces etc..). Today, it has become important to dispose of performing radiant heat transfer models in heat transfer and fluid mechanics simulation softwares, and well adapted to multidimensional industrial problems. This work presents the discrete ordinate radiant heat transfer model developed at the IRSID (the French institute of research in iron and steel metallurgy) and coupled with the PHOENICS heat transfer-fluid mechanics software. Three modeling approaches are presented concerning the radiative properties of gases (H{sub 2}O-CO{sub 2}). A ``weighted grey gases sum`` model gives satisfactory results for several 1-D validation cases. (J.S.) 20 refs.}
place = {France}
year = {1996}
month = {Dec}
}