Super-insulated wooden envelopes in Mediterranean climate: Summer overheating, thermal comfort optimization, environmental impact on an Italian case study

•Experimentation on a passive house in a Mediterranean climate.•Quantification of energy saving, comfort levels, environmental impact.•Optimal solution with inner massive layer and a proper ventilation strategy.•Discomfort reduction by 50%, 31% and 6% in temperate, semi-arid and desert zones. The ai...

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Bibliographic Details
Published inEnergy and buildings Vol. 138; pp. 716 - 732
Main Authors Stazi, Francesca, Tomassoni, Elisa, Di Perna, Costanzo
Format Journal Article
LanguageEnglish
Published Lausanne Elsevier B.V 01.03.2017
Elsevier BV
Subjects
Case studies
Clay
Climate
Computer programs
Computer simulation
Construction materials
Cooling
Data processing
Discomfort
Economic analysis
Economic models
Energy
Energy efficiency
Envelopes
Environmental impact
Environmental monitoring
Environmental sustainability
Green buildings
Indoor environments
Internal thermal inertia
Linings
Optimization
Overheating
Passive house
Residential buildings
Residential location
Specific heat
Summer
Super-insulation
Sustainability
Sustainable development
Thermal comfort
Thermodynamic properties
Ventilation
Wooden envelope
Italy
Passive house
Super-insulation
Thermal comfort
Environmental sustainability
Wooden envelope
Internal thermal inertia
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Summary:•Experimentation on a passive house in a Mediterranean climate.•Quantification of energy saving, comfort levels, environmental impact.•Optimal solution with inner massive layer and a proper ventilation strategy.•Discomfort reduction by 50%, 31% and 6% in temperate, semi-arid and desert zones. The aim of the study is to verify the actual performance of a super-insulated wooden envelope in a residential building located in a hot dry summer temperate climate and to optimize its thermal behavior favoring a dynamic interaction with the indoor environment. The method involved an integrated strategy between monitoring and calibrated simulations on experimental data and the simultaneous analysis of several aspects such as energy performance (EnergyPlus software), comfort (dynamic analysis with Fanger’s PMV comfort model) and environmental-economic sustainability (LCA analysis with SimaPro software). Parametric analyses were carried out to generalize the results to various usage patterns of plants and passive cooling techniques and to several climate zones. The study highlighted the presence of overheating phenomena and demonstrated that this problem can be solved or reduced through the adoption of appropriate passive strategies, such as massive inner linings combined with natural or hybrid ventilation. Appropriate values of internal areal heat capacity and decrement factor will configure comfortable and energy efficient solutions. In temperate climates the optimal solution, namely the adoption of a 12cm thick solid brick (or double dry clay panel) and natural ventilation, reduces the discomfort levels of 30–50%. In hottest periods of extreme climates the best solution, namely CMV+free-cooling combined with internal lightweight plaster, only slightly reduces the overheating with a 6% reduction of discomfort.
ISSN:0378-7788
1872-6178
DOI:10.1016/j.enbuild.2016.12.042