Investigating the performance of reflective insulation and low emissivity paints for the energy retrofit of roof attics

•The performance of a radiation control coating and reflective insulation was analysed.•A reduction in the indoor summer heat gains in the attic space was observed.•A reduction in the indoor summer surface temperature was observed.•A negligible effect was shown in the winter season. The energy retro...

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Bibliographic Details
Published in:Energy and buildings 2019-01, Vol.182, p.300-310
Main Authors: Fantucci, Stefano, Serra, Valentina
Format: Article
Language:English
Subjects:
Airspace
Aluminum
Attics
Buildings
Computer simulation
Cooling loads
Cooling systems
Dwellings
Emissivity
Energy
Heat exchange
Heat transfer
Insulation
Low emissivity
Mathematical models
Overheating
Paints
Radiation
Radiation control coatings
Reduction
Reflectance
Reflective insulation
Reflective paint
Retrofitting
Roof
Roofing
Roofs
Summer
Thermal resistance
Thermodynamic properties
Tiles
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Summary:•The performance of a radiation control coating and reflective insulation was analysed.•A reduction in the indoor summer heat gains in the attic space was observed.•A reduction in the indoor summer surface temperature was observed.•A negligible effect was shown in the winter season. The energy retrofitting and conversion of attic spaces into liveable dwelling units is a widely diffused practice in EU countries, and it leads to an increment in urban density, without having to construct new buildings. Roof surfaces are the parts of buildings that are exposed the most to the sun in summer season, and for this reason, they are responsible for high cooling loads, which can determine overheating phenomena in the dwellings below the attics. Different strategies that involve the use of extra-insulation or an increase in the solar reflectance of the outer layer can be adopted to resolve this problem. However, another solution that is sometimes adopted is the introduction of long-wave infra-red reflective insulations, which are generally applied below the roof tiles, facing an air cavity. This strategy allows the thermal resistance of a roof to be increased, as a result of a reduction in the radiation heat exchange, without having to increase the insulation thickness. In this study, an in-field experimental campaign has been carried out in Turin, Italy. The analysis was aimed at investigating the thermal behaviour of traditional roof adopting reflective insulation, made up of aluminium sheets, and of a new strategy, based on a treatment with low emissivity paint below the roof tiles. The experimental data were used to verify numerical 1D heat transfer simulations to account for the effect of the radiation heat exchange in the airspace below the roof tiles. The verified simulation models were used to analyse the effects of the insulation levels and of the emissivity properties of the reflective layer on the roof heat exchange. A reduction in the indoor summer heat gains of between ∼10% and ∼53% was found for roofs treated with refective insulation, depending on their emissivity properties, while the contribution to reducing the winter heat losses was negligible. The obtained results are encouraging and highlight that reflective insulation, used together with Low-E paints, represents a promising solution that can be used to help design attic retrofitting interventions, with the aim of achieving a better thermal performance in the summer period, and to address the requ
ISSN:0378-7788
1872-6178
DOI:10.1016/j.enbuild.2018.10.003