Quantification of workmanship insulation defects and their impact on the thermal performance of building facades

•Effective performance of insulations altered by practical defects is investigated.•Analytical models evaluate the effective thermal conductivity to use in simulation.•The energetic impact of common workmanship defects is studied.•The presence of openings in facade walls are found to be more harmful...

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Bibliographic Details
Published in:Applied energy 2016-03, Vol.165, p.272-284
Main Authors: Aïssani, A., Chateauneuf, A., Fontaine, J.-P., Audebert, Ph
Format: Article
Language:English
Subjects:
Computer simulation
Defects
Effective thermal conductivity
Insulation
Mathematical analysis
Mathematical models
Panels
Thermal conductivity
Uncertainties
Uncertainty
Workmanship defects
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Summary:•Effective performance of insulations altered by practical defects is investigated.•Analytical models evaluate the effective thermal conductivity to use in simulation.•The energetic impact of common workmanship defects is studied.•The presence of openings in facade walls are found to be more harmful. Nowadays, many performing insulation materials are available on the market. However, their expected thermal performance can be affected by many sources of uncertainty due to random errors that can occur during the manufacturing and the measurement processes. In addition, the thermal performance is strongly affected by another source of uncertainty related to the insulation laying process. As a matter of fact, defects in insulation panels are introduced either for practical reasons or due to a lack of rigor of workers. These errors are still not yet properly considered for simulation, although they result in significant heat losses. This work aims at investigating the impact of four common workmanship errors on the thermal performance of insulation panels. A coupling between experimental measurements and finite element modeling allows us to evaluate the effective thermal conductivity of insulations in presence of defects. The uncertainty analysis allows us to quantify the dispersion of insulation conductivity according to different types and sizes of defects, showing that flexible materials seem to be more affected by the defects. For simulation purpose, analytical models are proposed to assess the effective thermal conductivity in terms of size and type of defects. The numerical application to insulated wall shows the impact of each defect on the energy consumption, where deep grooves and openings are found to be strongly affecting the insulation performance.
ISSN:0306-2619
1872-9118
DOI:10.1016/j.apenergy.2015.12.040