The effect of surface roughness and emissivity on radiator output

The effect of surface roughness and emissivity on radiator output

The effect of altering the emissivity and the roughness of a wall behind a radiator on the radiator heat output has been studied experimentally and by using computational fluid dynamics. The results of a 3D RNG k– ɛ turbulent model agree well with, and have the same trend as, the experimental result...

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Bibliographic Details
Published in:Energy and buildings Vol. 43; no. 2; pp. 400 - 406
Main Authors: Shati, A.K.A., Blakey, S.G., Beck, S.B.M.
Format: Journal Article
Language:English
Published: Oxford Elsevier B.V 01-02-2011
Elsevier
Subjects:
Applied sciences
Building technical equipments
Buildings
Buildings. Public works
Computational fluid dynamics
Domestic panel radiators
Emissivity
Environmental engineering
Exact sciences and technology
Free convection
Heat transfer
Radiation
Radiators
Roughness
Space heating
Surface emissivity
Surface roughness
Turbulence
Walls
Surface emissivity
Surface roughness
Domestic panel radiators
Free convection
Heat transfer
Radiation
Computational fluid dynamics
Roughness
Experimental study
Modeling
Convection
Household heating
Emissivity
Experimental result
Radiator
Comparative study
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Summary:The effect of altering the emissivity and the roughness of a wall behind a radiator on the radiator heat output has been studied experimentally and by using computational fluid dynamics. The results of a 3D RNG k– ɛ turbulent model agree well with, and have the same trend as, the experimental results. The results indicate that the presence of large scale surface roughness and a high emissivity surface increases both the heat flow rate and the air velocity behind the radiator compared to a smooth shiny surface. The former increases the wall surface emissivity which causes the surface temperature of the wall to increase, effectively creating additional convective heat transfer surface. The surface roughness will increase both the surface area for heat transfer and the turbulent intensity which increase the mass transfer and free convective heat flux through the air gap. The results indicate that the heat transfer can be increased by about 26% through the use of a high emissivity saw-tooth surface compared to a smooth shiny one. This means that using a wall surface with high roughness and emissivity behind the radiator will increase the heat output from the radiator.
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ISSN:0378-7788
DOI:10.1016/j.enbuild.2010.10.002