Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Climate adaptive optimization of green roofs and natural night ventilation for lifespan energy performance improvement in office buildings
https://orcid.org/0000-0003-4325-6519
https://orcid.org/0000-0002-4050-3740
Abstract Green roofs and natural night ventilation are highly coupled and complementary techniques to improve building energy efficiency, but previous studies have not fully explored the synergetic benefits of combining two technologies. Furthermore, the traditional method of design optimization using Typical Meteorological Year (TMY) weather data falls short of providing climate-adaptive designs for new buildings that react differently to weather changes, as well as capturing the applicability and uncertainty of yearly weather variations. Therefore, building long-term performance in practice often deviates significantly from its design expectation. To quantitatively assess the energy savings when integrating green roofs and night ventilation (GR-NV) while taking future long-term weather impacts into account, this study proposes a systematic approach that integrates field testing, sensitivity analysis, building energy simulation, and climate adaptive optimization. The proposed approach is validated and demonstrated in an office building in Chongqing, China. The results show that Chongqing's annual mean air temperature in 2050 would climb by 2.4 °C in comparison to that of TMY. With the global warming effects, the annual night ventilation hours and the amount of sensible heat dissipated by NV increased by 78 h (13.2%) and 15.8 MJ/m2 (18.7%) from 1991 to 2050. The choice of plant species in the GR-NV system would also be impacted by global warming. The optimal design alternative based on FMY could reduce annual energy use by up to 5.07 kWh/m2 (12.2%) in new buildings.
Highlights Lifespan energy performance of GR-NV systems in office buildings is explored. Annual mean air temperature would climb by 2.1 °C from 2021 to 2050 based on GCMs. Global warming affects the optimal choice of plant species in GR-NV systems. Annual night ventilation hours increased by 13.2% from 1991 to 2050. Optimal design alternative based on FMY reduces annual energy use by up to 12.2%.
Climate adaptive optimization of green roofs and natural night ventilation for lifespan energy performance improvement in office buildings
https://orcid.org/0000-0003-4325-6519
https://orcid.org/0000-0002-4050-3740
Abstract Green roofs and natural night ventilation are highly coupled and complementary techniques to improve building energy efficiency, but previous studies have not fully explored the synergetic benefits of combining two technologies. Furthermore, the traditional method of design optimization using Typical Meteorological Year (TMY) weather data falls short of providing climate-adaptive designs for new buildings that react differently to weather changes, as well as capturing the applicability and uncertainty of yearly weather variations. Therefore, building long-term performance in practice often deviates significantly from its design expectation. To quantitatively assess the energy savings when integrating green roofs and night ventilation (GR-NV) while taking future long-term weather impacts into account, this study proposes a systematic approach that integrates field testing, sensitivity analysis, building energy simulation, and climate adaptive optimization. The proposed approach is validated and demonstrated in an office building in Chongqing, China. The results show that Chongqing's annual mean air temperature in 2050 would climb by 2.4 °C in comparison to that of TMY. With the global warming effects, the annual night ventilation hours and the amount of sensible heat dissipated by NV increased by 78 h (13.2%) and 15.8 MJ/m2 (18.7%) from 1991 to 2050. The choice of plant species in the GR-NV system would also be impacted by global warming. The optimal design alternative based on FMY could reduce annual energy use by up to 5.07 kWh/m2 (12.2%) in new buildings.
Highlights Lifespan energy performance of GR-NV systems in office buildings is explored. Annual mean air temperature would climb by 2.1 °C from 2021 to 2050 based on GCMs. Global warming affects the optimal choice of plant species in GR-NV systems. Annual night ventilation hours increased by 13.2% from 1991 to 2050. Optimal design alternative based on FMY reduces annual energy use by up to 12.2%.
Climate adaptive optimization of green roofs and natural night ventilation for lifespan energy performance improvement in office buildings
https://orcid.org/0000-0003-4325-6519
https://orcid.org/0000-0002-4050-3740
Abstract Green roofs and natural night ventilation are highly coupled and complementary techniques to improve building energy efficiency, but previous studies have not fully explored the synergetic benefits of combining two technologies. Furthermore, the traditional method of design optimization using Typical Meteorological Year (TMY) weather data falls short of providing climate-adaptive designs for new buildings that react differently to weather changes, as well as capturing the applicability and uncertainty of yearly weather variations. Therefore, building long-term performance in practice often deviates significantly from its design expectation. To quantitatively assess the energy savings when integrating green roofs and night ventilation (GR-NV) while taking future long-term weather impacts into account, this study proposes a systematic approach that integrates field testing, sensitivity analysis, building energy simulation, and climate adaptive optimization. The proposed approach is validated and demonstrated in an office building in Chongqing, China. The results show that Chongqing's annual mean air temperature in 2050 would climb by 2.4 °C in comparison to that of TMY. With the global warming effects, the annual night ventilation hours and the amount of sensible heat dissipated by NV increased by 78 h (13.2%) and 15.8 MJ/m2 (18.7%) from 1991 to 2050. The choice of plant species in the GR-NV system would also be impacted by global warming. The optimal design alternative based on FMY could reduce annual energy use by up to 5.07 kWh/m2 (12.2%) in new buildings.
Highlights Lifespan energy performance of GR-NV systems in office buildings is explored. Annual mean air temperature would climb by 2.1 °C from 2021 to 2050 based on GCMs. Global warming affects the optimal choice of plant species in GR-NV systems. Annual night ventilation hours increased by 13.2% from 1991 to 2050. Optimal design alternative based on FMY reduces annual energy use by up to 12.2%.
Climate adaptive optimization of green roofs and natural night ventilation for lifespan energy performance improvement in office buildings
Shi, Dachuan (Autor:in) / Gao, Yafeng (Autor:in) / Zeng, Peng (Autor:in) / Li, Baizhan (Autor:in) / Shen, Pengyuan (Autor:in) / Zhuang, Chaoqun (Autor:in)
Building and Environment ; 223
14.08.2022
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
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