Estimation of thermophysical properties using natural signal analysis with heat and moisture transfer model

Conduction heat transfer through opaque envelope components characterizes the thermal performance of buildings and its consequences in terms of energy consumption and thermal comfort. A building envelope can be thermally described by two parameters: thermal conductivity ( λ) and heat capacity ( ρ· c...

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Bibliographic Details
Published in:Energy and buildings 2009-12, Vol.41 (12), p.1360-1367
Main Authors: Ordenes, M., Lamberts, R., Güths, S.
Format: Article
Language:English
Subjects:
Applied sciences
Buildings
Buildings. Public works
Computation methods. Tables. Charts
Estimation of thermophysical properties
Exact sciences and technology
External envelopes
Heat and moisture simulation
Non-destructive test
Structural analysis. Stresses
Wall. Partition
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Summary:Conduction heat transfer through opaque envelope components characterizes the thermal performance of buildings and its consequences in terms of energy consumption and thermal comfort. A building envelope can be thermally described by two parameters: thermal conductivity ( λ) and heat capacity ( ρ· c). Estimating these thermal properties in situ allows the characterization of real building elements considering different aspects, such as thermal behavior under specific weather conditions, quality variability in materials, local construction technologies and material deterioration. This paper presents a method to estimate the thermal conductivity and volumetric heat capacity of a homogeneous element using a non-destructive test considering natural oscillations. Surface temperature and heat flow are measured in a concrete sample (with known thermal properties) and the data is treated with a signal processing technique. Estimation is carried out with a heat and moisture transfer model. Measurements were performed on six separate days under different sky conditions within a period of one month, to determine the importance of solar radiation as a heat source. Results gave acceptable estimates (average inaccuracy of 10–14%) of both thermophysical properties.
ISSN:0378-7788
DOI:10.1016/j.enbuild.2009.08.008