A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Historic building energy conservation with wooden attic using vacuum insulation panel retrofit technology
https://orcid.org/0000-0003-2278-5278
Abstract The envelopes in historic buildings must be preserved as aging historic buildings continue to be used. Conservation is necessary to improve the energy performance of historic buildings. The target building of this study has an exposed rafter structure. Modern historical buildings in Korea do not have a passive retrofit, which is insulation. The passive retrofit covering the roof structure needs to be applied taking into account the original protection of the exposed rafters. This study aims to examine the energy improvement effect of a historic building with a roof with an exposed rafter structure. Considering the characteristics of the building, a vacuum insulation panel (VIP) retrofit technology is used instead of general insulation. The VIP is thin and has high heat resistance, so there is little damage to the envelope of historic buildings, and the U-value of the existing roof layer is reduced by 88%. By applying retrofitting technology, the annual energy consumption of the top floor was improved by 55%. Cooling on the top floor showed an improvement of 29.87%. The largest energy savings occurred in May at 49%. This is because the VIP retrofit technology is applied in the form of external insulation. External insulation lowers heat storage owing to solar radiation. The developed VIP was suitable for Korea's preservation considerations and building energy conservation considerations.
Highlights Exposed rafters have Korean aesthetic value and must be preserved. Exterior insulation scenarios are proposed to preserve the uninsulated roof. The 0.015 m VIP is suitable for minimizing the exterior deformation of historic buildings. Energy simulation uses to overcome the limitations of applying retrofit technology.
Historic building energy conservation with wooden attic using vacuum insulation panel retrofit technology
https://orcid.org/0000-0003-2278-5278
Abstract The envelopes in historic buildings must be preserved as aging historic buildings continue to be used. Conservation is necessary to improve the energy performance of historic buildings. The target building of this study has an exposed rafter structure. Modern historical buildings in Korea do not have a passive retrofit, which is insulation. The passive retrofit covering the roof structure needs to be applied taking into account the original protection of the exposed rafters. This study aims to examine the energy improvement effect of a historic building with a roof with an exposed rafter structure. Considering the characteristics of the building, a vacuum insulation panel (VIP) retrofit technology is used instead of general insulation. The VIP is thin and has high heat resistance, so there is little damage to the envelope of historic buildings, and the U-value of the existing roof layer is reduced by 88%. By applying retrofitting technology, the annual energy consumption of the top floor was improved by 55%. Cooling on the top floor showed an improvement of 29.87%. The largest energy savings occurred in May at 49%. This is because the VIP retrofit technology is applied in the form of external insulation. External insulation lowers heat storage owing to solar radiation. The developed VIP was suitable for Korea's preservation considerations and building energy conservation considerations.
Highlights Exposed rafters have Korean aesthetic value and must be preserved. Exterior insulation scenarios are proposed to preserve the uninsulated roof. The 0.015 m VIP is suitable for minimizing the exterior deformation of historic buildings. Energy simulation uses to overcome the limitations of applying retrofit technology.
Historic building energy conservation with wooden attic using vacuum insulation panel retrofit technology
https://orcid.org/0000-0003-2278-5278
Abstract The envelopes in historic buildings must be preserved as aging historic buildings continue to be used. Conservation is necessary to improve the energy performance of historic buildings. The target building of this study has an exposed rafter structure. Modern historical buildings in Korea do not have a passive retrofit, which is insulation. The passive retrofit covering the roof structure needs to be applied taking into account the original protection of the exposed rafters. This study aims to examine the energy improvement effect of a historic building with a roof with an exposed rafter structure. Considering the characteristics of the building, a vacuum insulation panel (VIP) retrofit technology is used instead of general insulation. The VIP is thin and has high heat resistance, so there is little damage to the envelope of historic buildings, and the U-value of the existing roof layer is reduced by 88%. By applying retrofitting technology, the annual energy consumption of the top floor was improved by 55%. Cooling on the top floor showed an improvement of 29.87%. The largest energy savings occurred in May at 49%. This is because the VIP retrofit technology is applied in the form of external insulation. External insulation lowers heat storage owing to solar radiation. The developed VIP was suitable for Korea's preservation considerations and building energy conservation considerations.
Highlights Exposed rafters have Korean aesthetic value and must be preserved. Exterior insulation scenarios are proposed to preserve the uninsulated roof. The 0.015 m VIP is suitable for minimizing the exterior deformation of historic buildings. Energy simulation uses to overcome the limitations of applying retrofit technology.
Historic building energy conservation with wooden attic using vacuum insulation panel retrofit technology
Yuk, Hyeonseong (author) / Choi, Ji Yong (author) / Kim, Young Uk (author) / Chang, Seong Jin (author) / Kim, Sumin (author)
Building and Environment ; 230
2023-01-09
Article (Journal)
Electronic Resource
English
| British Library Online Contents | 2009