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Investigating the Potential of Latent Heat in Hygroscopic Insulating Materials

Ranefjärd, Oskar LU ; Rosenkilde, Anders LU ; Niklewski, Jonas LU ; Hansson, Eva Frühwald LU and Strandberg-De Bruijn, Paulien (2022) 15th International Conference on Thermal Performance of the Exterior Envelopes of Whole Buildings 2022 In Thermal Performance of the Exterior Envelopes of Whole Buildings p.85-94
Abstract

Energy from buildings accounts for almost 40% of global energy-related carbon emissions. A way to reduce both energy consumption in buildings as well as their environmental impact is to use bio-based insulation materials such as cellulose, wood or hemp fiber insulation. Experiences from modern buildings built with a timber-frame structure and insulated with bio-based materials show that these buildings have lower energy needs in the operational phase than what was initially expected from energy simulation models. However, these experiences have thus far been anecdotal, and they have not yet been validated through measurements. It is common that energy models only focus on thermal properties of materials and thermal flows through the... (More)

Energy from buildings accounts for almost 40% of global energy-related carbon emissions. A way to reduce both energy consumption in buildings as well as their environmental impact is to use bio-based insulation materials such as cellulose, wood or hemp fiber insulation. Experiences from modern buildings built with a timber-frame structure and insulated with bio-based materials show that these buildings have lower energy needs in the operational phase than what was initially expected from energy simulation models. However, these experiences have thus far been anecdotal, and they have not yet been validated through measurements. It is common that energy models only focus on thermal properties of materials and thermal flows through the building envelope, without considering moisture loads or hygrothermal behavior of building materials. A relevant difference between bio-based insulation materials and their polystyrene or mineral wool-based counterparts is that the former is more hygroscopic, with a generally high moisture capacity. It is hypothesized that latent heat and moisture transfer from the higher hygroscopicity of bio-based insulation materials could account for the discrepancy between modelled energy needs and measured energy needs in the operational phase. A numerical study was conducted to evaluate the energy performance of materials with varying hygroscopic properties. A numerical model of an exterior wall assembly with hygroscopic insulation materials was created in COMSOL, enabling parameters to be varied, without the manual input commonly required by some other commercial programs. Studied parameters included moisture buffering capacity and insulation thickness. Furthermore, the influence of the indoor and outdoor climate on the hygrothermal performance of the wall assembly was studied. The output evaluated focused primarily on the heat flux through the wall from the interior side. Results of the study showed that there is a potential for energy saving using hygroscopic insulation materials, as their higher moisture capacity could contribute to reduced energy needs for space heating. Results from this study also indicate that latent heat should be evaluated when insulation materials with hygroscopic properties are used in the building envelope, otherwise the energy use from heating could be underestimated.

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author
; ; ; and
organization
publishing date
type
Chapter in Book/Report/Conference proceeding
publication status
published
subject
host publication
Thermal Performance of the Exterior Envelopes of Whole Buildings XV International Conference
series title
Thermal Performance of the Exterior Envelopes of Whole Buildings
pages
10 pages
publisher
American Society of Heating Refrigerating and Air-Conditioning Engineers
conference name
15th International Conference on Thermal Performance of the Exterior Envelopes of Whole Buildings 2022
conference location
Clearwater Beach, United States
conference dates
2022-12-05 - 2022-12-08
external identifiers
  • scopus:85167599172
ISSN
2166-8469
ISBN
9781955516280
language
English
LU publication?
yes
additional info
Funding Information: This research was carried out in the project “Biobased houses in industrial construction” within BioInnovation “Möjliggörande teknologier för biobaserade produkter”, an innovation program financed by Vinnova, the Swedish Energy Agency and the Swedish Research Council Formas, TMF-Swedish Federation of Wood and Furniture Industry and by the industrial participants. Publisher Copyright: © 2022 ASHRAE.
id
73756551-8bf0-40b1-ae8e-996c60f39461
date added to LUP
2023-08-23 10:09:25
date last changed
2023-11-07 11:06:34
@inproceedings{73756551-8bf0-40b1-ae8e-996c60f39461,
  abstract     = {{<p>Energy from buildings accounts for almost 40% of global energy-related carbon emissions. A way to reduce both energy consumption in buildings as well as their environmental impact is to use bio-based insulation materials such as cellulose, wood or hemp fiber insulation. Experiences from modern buildings built with a timber-frame structure and insulated with bio-based materials show that these buildings have lower energy needs in the operational phase than what was initially expected from energy simulation models. However, these experiences have thus far been anecdotal, and they have not yet been validated through measurements. It is common that energy models only focus on thermal properties of materials and thermal flows through the building envelope, without considering moisture loads or hygrothermal behavior of building materials. A relevant difference between bio-based insulation materials and their polystyrene or mineral wool-based counterparts is that the former is more hygroscopic, with a generally high moisture capacity. It is hypothesized that latent heat and moisture transfer from the higher hygroscopicity of bio-based insulation materials could account for the discrepancy between modelled energy needs and measured energy needs in the operational phase. A numerical study was conducted to evaluate the energy performance of materials with varying hygroscopic properties. A numerical model of an exterior wall assembly with hygroscopic insulation materials was created in COMSOL, enabling parameters to be varied, without the manual input commonly required by some other commercial programs. Studied parameters included moisture buffering capacity and insulation thickness. Furthermore, the influence of the indoor and outdoor climate on the hygrothermal performance of the wall assembly was studied. The output evaluated focused primarily on the heat flux through the wall from the interior side. Results of the study showed that there is a potential for energy saving using hygroscopic insulation materials, as their higher moisture capacity could contribute to reduced energy needs for space heating. Results from this study also indicate that latent heat should be evaluated when insulation materials with hygroscopic properties are used in the building envelope, otherwise the energy use from heating could be underestimated.</p>}},
  author       = {{Ranefjärd, Oskar and Rosenkilde, Anders and Niklewski, Jonas and Hansson, Eva Frühwald and Strandberg-De Bruijn, Paulien}},
  booktitle    = {{Thermal Performance of the Exterior Envelopes of Whole Buildings XV International Conference}},
  isbn         = {{9781955516280}},
  issn         = {{2166-8469}},
  language     = {{eng}},
  pages        = {{85--94}},
  publisher    = {{American Society of Heating Refrigerating and Air-Conditioning Engineers}},
  series       = {{Thermal Performance of the Exterior Envelopes of Whole Buildings}},
  title        = {{Investigating the Potential of Latent Heat in Hygroscopic Insulating Materials}},
  year         = {{2022}},
}