A Simplified Model for Radiative Transfer in Building Enclosures With Low Emissivity Walls: Development and Application to Radiant Barrier Insulation

This paper deals with a simplified model of radiative heat transfer in building enclosures with low emissivity walls. The approach is based on an existing simplified model, well known and used in building multizone simulation codes, for the long wave exchanges in building enclosures. This method is simply extended to the case of a cavity including a very low emissivity wall, and it is shown that the obtained formalism is similar to the one used in the case of the based model, convenient for enclosures with only black walls (blackbody assumption). The proposed model has been integrated into a building simulation code and is based on simple examples; it is shown that intermediate results between the imprecise initial simple model and the more precise detailed model, the net-radiosity method, can be obtained. Finally, an application of the model is made for an existing experimental test cell including a radiant barrier insulation product, well used in Reunion Island for thermal insulation of roofs. With an efficacy based on the very low emissivity of their surfaces and the consequent decrease in radiative heat transfer through the wall in which they are included, the proposed simplified model leads to results very close to those of the reference method, the net-radiosity method.

[1]  M. Woloszyn,et al.  Modélisation hygro-thermo-aéraulique des bâtiments multizones : proposition d'une stratégie de résolution du système couple , 1999 .

[2]  Joseph Andrew Clarke,et al.  Energy Simulation in Building Design , 1985 .

[3]  W. P. Levins,et al.  Measured effects of dust on the performance of radiant barriers installed on top of attic insulation , 1990 .

[4]  Mario A. Medina,et al.  On the performance of radiant barriers in combination with different attic insulation levels , 2000 .

[5]  M. A. Medina,et al.  Effect of attic ventilation on the performance of radiant barriers , 1992 .

[6]  M. Hollingsworth Experimental determination of the thermal resistance insulations , 1983 .

[7]  Y. Jaluria,et al.  An Introduction to Heat Transfer , 1950 .

[8]  Antoine Roldan Etude thermique et aéraulique des enveloppes de bâtiment : influence des couplages intérieurs et du multizonage , 1985 .

[9]  Andre Omer Desjarlais,et al.  Prediction of the Thermal Performance of Single and Multi-Airspace Reflective Insulation Materials , 1991 .

[10]  Mario A. Medina,et al.  A Transient Heat and Mass Transfer Model of Residential Attics Used to Simulate Radiant Barrier Retrofits, Part II: Validation and Simulations , 1998 .

[11]  François Garde,et al.  A multimodel approach to building thermal simulation for design and research purposes , 2012, ArXiv.

[12]  David W. Winiarski,et al.  A quasi-steady-state model of attic heat transfer with radiant barriers , 1996 .

[13]  W. D. Turner,et al.  A model of the effect of dust on the emissivity of radiant barriers , 1994 .

[14]  M. Pinar Mengüç,et al.  Thermal Radiation Heat Transfer , 2020 .

[15]  Harry Boyer,et al.  A combined approach for determining the thermal performance of radiant barriers under field conditions , 2008 .

[16]  Mario A. Medina,et al.  A Transient Heat and Mass Transfer Model of Residential Attics Used to Simulate Radiant Barrier Retrofits, Part I: Development , 1998 .

[17]  François Garde,et al.  On the thermal behaviour of roof-mounted radiant barriers under tropical and humid climatic conditions: modelling and empirical validation , 2003 .