Evaluation of Optimum Thermal Insulation for Mass Walls in Severe Solar Climates of Northern Chile

Evaluation of Optimum Thermal Insulation for Mass Walls in Severe Solar Climates of Northern Chile

The Life Cycle Cost Assessment (LCCA) methodology is widely used to determine the optimal thickness of thermal insulation for walls and roofs. The results depend on several factors, such as the degree day calculations method, the ambient or sol–air temperature, base temperature variations, and the h...

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Bibliographic Details
Main Authors: Konstantin Verichev, Carmen Díaz-López, Gerardo Loncomilla Huenupán, Andrés García-Ruiz
Format: Article
Language:English
Published: MDPI AG 2025-07-01
Series:Buildings
Subjects:
life cycle cost analysis
solar radiation
sustainable construction
thermal insulation
optimum thickness
energy demand
Online Access:https://www.mdpi.com/2075-5309/15/14/2580
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Summary:The Life Cycle Cost Assessment (LCCA) methodology is widely used to determine the optimal thickness of thermal insulation for walls and roofs. The results depend on several factors, such as the degree day calculations method, the ambient or sol–air temperature, base temperature variations, and the heat capacity of the thermal envelope elements. This study aims to analyze the impact of solar radiation on mass walls with different orientations in five cities in northern Chile, which have severe solar climates. The goal is to determine the optimal thickness of expanded polystyrene insulation using the LCCA method, considering solar radiation, a varying base temperature, and validating results by analyzing the energy demand for heating and cooling of a typical house. The findings show that excluding solar radiation in the LCCA methodology can lead to an underestimation of the optimal insulation thickness by 21–39% for walls in northern Chile. It was also found that using variable monthly threshold temperatures for heating and cooling based on the adaptive thermal comfort model results in a slight underestimation (1–3%) of the optimal thickness compared to a constant annual temperature. An energy simulation of a typical house in five cities in northern Chile showed that neglecting the effect of solar radiation when determining the thermal insulation thickness for the studied wall can lead to a minor increase in heating and cooling energy demand, ranging from approximately 1% to 9%. However, this study emphasizes the importance of applying optimal insulation thickness for cities with more continental climates like Santiago and Calama, where the heating demand is higher than cooling.
ISSN:2075-5309

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