The effect of moisture transportation on energy efficiency and IAQ in residential buildings

•This study investigates the effect of moisture transport on the overall building performance.•We validate a hygrothermal model with an apartment house.•We study on energy efficiency, thermal comfort and mould growth risk.•Building energy consumption could be underestimated without considering moist...

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Published in	Energy and buildings Vol. 75; pp. 439 - 446
Main Authors	Moon, Hyeun Jun, Ryu, Seung Ho, Kim, Jeong Tai
Format	Journal Article
Language	English
Published	Oxford Elsevier B.V 01.06.2014 Elsevier
Subjects	Applied sciences Building energy Building energy simulation Building insulation Buildings Buildings. Public works Exact sciences and technology External envelopes Hygrothermal simulation IAQ Moisture transportation Pollution indoor buildings Residential building Thermal comfort Types of buildings Wall. Partition IAQ Hygrothermal simulation Moisture transportation Building energy simulation Building energy Hygrothermal variation Thermal comfort Humidity transfer Indoor climate Air quality Modeling Residential building External envelope Analysis method Simulation Energetic efficiency
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ISSN	0378-7788
DOI	10.1016/j.enbuild.2014.02.039

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Abstract	•This study investigates the effect of moisture transport on the overall building performance.•We validate a hygrothermal model with an apartment house.•We study on energy efficiency, thermal comfort and mould growth risk.•Building energy consumption could be underestimated without considering moisture transport. The building envelope is normally subject to thermal and moisture gradients in practice. Due to the interrelationship, thermal and moisture transfer should be simultaneously calculated for an accurate building performance evaluation. The aim of this study is to investigate the effect of moisture transportation on energy efficiency, thermal comfort and mould growth risks in residential buildings based on the hygrothermal simulation. First, hygrothermal simulation is conducted to evaluate the energy efficiency and IAQ in the selected residential building. This paper also provides characteristics of the hygrothermal properties of domestic building materials which are used for the selected residential building. Differences between experimental data for the domestic materials and properties from embedded data in the hygrothermal simulation program are discussed. Second, a hygrothermal calculation model is calibrated with the measurement data for indoor air temperature and relative humidity in the selected residential building. Lastly, we illustrate the effect of moisture transfer on the overall building performance by comparing the hygrothermal simulation results with thermal-only simulation (only consideration of heat transfer through the building envelope) results. The results suggest that heating and cooling energy can be underestimated without consideration of moisture transportation mechanisms in the building energy simulation. Moreover, results show that the moisture buffering effect could significantly reduce the amplitude of relative humidity fluctuations during all seasons.
AbstractList	The building envelope is normally subject to thermal and moisture gradients in practice. Due to the interrelationship, thermal and moisture transfer should be simultaneously calculated for an accurate building performance evaluation. The aim of this study is to investigate the effect of moisture transportation on energy efficiency, thermal comfort and mould growth risks in residential buildings based on the hygrothermal simulation. First, hygrothermal simulation is conducted to evaluate the energy efficiency and IAQ in the selected residential building. This paper also provides characteristics of the hygrothermal properties of domestic building materials which are used for the selected residential building. Differences between experimental data for the domestic materials and properties from embedded data in the hygrothermal simulation program are discussed. Second, a hygrothermal calculation model is calibrated with the measurement data for indoor air temperature and relative humidity in the selected residential building. Lastly, we illustrate the effect of moisture transfer on the overall building performance by comparing the hygrothermal simulation results with thermal-only simulation (only consideration of heat transfer through the building envelope) results. The results suggest that heating and cooling energy can be underestimated without consideration of moisture transportation mechanisms in the building energy simulation. Moreover, results show that the moisture buffering effect could significantly reduce the amplitude of relative humidity fluctuations during all seasons. •This study investigates the effect of moisture transport on the overall building performance.•We validate a hygrothermal model with an apartment house.•We study on energy efficiency, thermal comfort and mould growth risk.•Building energy consumption could be underestimated without considering moisture transport. The building envelope is normally subject to thermal and moisture gradients in practice. Due to the interrelationship, thermal and moisture transfer should be simultaneously calculated for an accurate building performance evaluation. The aim of this study is to investigate the effect of moisture transportation on energy efficiency, thermal comfort and mould growth risks in residential buildings based on the hygrothermal simulation. First, hygrothermal simulation is conducted to evaluate the energy efficiency and IAQ in the selected residential building. This paper also provides characteristics of the hygrothermal properties of domestic building materials which are used for the selected residential building. Differences between experimental data for the domestic materials and properties from embedded data in the hygrothermal simulation program are discussed. Second, a hygrothermal calculation model is calibrated with the measurement data for indoor air temperature and relative humidity in the selected residential building. Lastly, we illustrate the effect of moisture transfer on the overall building performance by comparing the hygrothermal simulation results with thermal-only simulation (only consideration of heat transfer through the building envelope) results. The results suggest that heating and cooling energy can be underestimated without consideration of moisture transportation mechanisms in the building energy simulation. Moreover, results show that the moisture buffering effect could significantly reduce the amplitude of relative humidity fluctuations during all seasons.
Author	Ryu, Seung Ho Kim, Jeong Tai Moon, Hyeun Jun
Author_xml	– sequence: 1 givenname: Hyeun Jun surname: Moon fullname: Moon, Hyeun Jun organization: Department of Architectural Engineering, Dankook University, Yongin 448-701, Republic of Korea – sequence: 2 givenname: Seung Ho surname: Ryu fullname: Ryu, Seung Ho email: lemon415@dankook.ac.kr organization: Department of Architectural Engineering, Dankook University, Yongin 448-701, Republic of Korea – sequence: 3 givenname: Jeong Tai surname: Kim fullname: Kim, Jeong Tai organization: Department of Architectural Engineering, Kyung Hee University, Yongin 446-701, Republic of Korea
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Keywords	IAQ Hygrothermal simulation Moisture transportation Building energy simulation Building energy Hygrothermal variation Thermal comfort Humidity transfer Indoor climate Air quality Modeling Residential building External envelope Analysis method Simulation Energetic efficiency
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Snippet	•This study investigates the effect of moisture transport on the overall building performance.•We validate a hygrothermal model with an apartment house.•We... The building envelope is normally subject to thermal and moisture gradients in practice. Due to the interrelationship, thermal and moisture transfer should be...
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SubjectTerms	Applied sciences Building energy Building energy simulation Building insulation Buildings Buildings. Public works Exact sciences and technology External envelopes Hygrothermal simulation IAQ Moisture transportation Pollution indoor buildings Residential building Thermal comfort Types of buildings Wall. Partition
Title	The effect of moisture transportation on energy efficiency and IAQ in residential buildings
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