Thermal Behavior in Glass Houses through the Analysis of Scale Models

Reducing energy expenditure in the construction sector requires the implementation of passive strategies in buildings. In Spain, consumption is centered on air conditioning systems associated with the demand for the building’s thermal envelope. A critical point of the enclosures is represented by gl...

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Published in:Sustainability 2021-07, Vol.13 (14), p.7970
Main Authors: Aguilera-Benito, Patricia, Varela-Lujan, Sheila, Piña-Ramirez, Carolina
Format: Article
Language:English
Subjects:
Air conditioning
Alternative energy sources
Buildings
Construction
Construction industry
Corporate image
Cost control
COVID-19
Critical point
Design
Energy consumption
Energy efficiency
Environmental impact
Foils
Heat
Maintenance costs
Renewable resources
Residential areas
Scale models
Solar energy
Sustainability
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cited_by cdi_FETCH-LOGICAL-c295t-9e0b434f26bfbe745ba11b929f1f7757e707572c13f48b6ae3a61af9479004c3
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container_issue 14
container_start_page 7970
container_title Sustainability
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creator Aguilera-Benito, Patricia
Varela-Lujan, Sheila
Piña-Ramirez, Carolina
description Reducing energy expenditure in the construction sector requires the implementation of passive strategies in buildings. In Spain, consumption is centered on air conditioning systems associated with the demand for the building’s thermal envelope. A critical point of the enclosures is represented by glazed holes where much of the energy that is consumed is lost; however, homes increasingly tend to have large window openings due to the comfort and visual well-being they provide to users. In this study, we focus on an extreme case, analyzing a fully glazed house in its four orientations. It is necessary to evaluate the most energy efficient passive strategy for this type of construction. The results are based on the temperature analysis obtained during the monitoring of two scale models of a glass house. The results indicate that solar control foil glasses perform better in warmer weather stations. Regarding the cantilever installation, it influences the interior temperature and the central hours of the day, mitigating the increase in temperature as well as slowing the nighttime cooling.
doi_str_mv 10.3390/su13147970
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source Publicly Available Content Database; Coronavirus Research Database
subjects Air conditioning
Alternative energy sources
Buildings
Construction
Construction industry
Corporate image
Cost control
COVID-19
Critical point
Design
Energy consumption
Energy efficiency
Environmental impact
Foils
Heat
Maintenance costs
Renewable resources
Residential areas
Scale models
Solar energy
Sustainability
title Thermal Behavior in Glass Houses through the Analysis of Scale Models
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