Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Building Resilience to Heatwaves : Parametric Simulation Approach Aiding Passive Design Strategies for Thermal Comfort in Future Climate
https://orcid.org/0009-0005-7901-5129
Future weather predictions indicate more frequent and intense heatwaves, demanding that buildings ensure adequate comfort during those events. Current research focuses on climate adaptation and estimating thermal comfort with rising temperatures. This study investigates heatwaveresilient architecture, particularly where air conditioning is unavailable and cooling relies on passive strategies. Numerous simulations were conducted on a simplified building model using future-updated weather data and a parametric approach. This method enabled a detailed exploration of the effects of specific parameters (One-at-a-time Sensitivity Analysis) on thermal comfort during early design stages. The results suggest that buildings without mechanical air conditioning will struggle to maintain thermal comfort. The most influential parameters were window shading style, solar heat gain coefficient, and window-to-wall ratio. The main contribution of this study is developing a highly applicable model for a medium-sized residential building and a sensitivity analysis of thermal comfort during heatwaves, considering key geometric and physical parameters.
Building Resilience to Heatwaves : Parametric Simulation Approach Aiding Passive Design Strategies for Thermal Comfort in Future Climate
https://orcid.org/0009-0005-7901-5129
Future weather predictions indicate more frequent and intense heatwaves, demanding that buildings ensure adequate comfort during those events. Current research focuses on climate adaptation and estimating thermal comfort with rising temperatures. This study investigates heatwaveresilient architecture, particularly where air conditioning is unavailable and cooling relies on passive strategies. Numerous simulations were conducted on a simplified building model using future-updated weather data and a parametric approach. This method enabled a detailed exploration of the effects of specific parameters (One-at-a-time Sensitivity Analysis) on thermal comfort during early design stages. The results suggest that buildings without mechanical air conditioning will struggle to maintain thermal comfort. The most influential parameters were window shading style, solar heat gain coefficient, and window-to-wall ratio. The main contribution of this study is developing a highly applicable model for a medium-sized residential building and a sensitivity analysis of thermal comfort during heatwaves, considering key geometric and physical parameters.
Building Resilience to Heatwaves : Parametric Simulation Approach Aiding Passive Design Strategies for Thermal Comfort in Future Climate
https://orcid.org/0009-0005-7901-5129
Future weather predictions indicate more frequent and intense heatwaves, demanding that buildings ensure adequate comfort during those events. Current research focuses on climate adaptation and estimating thermal comfort with rising temperatures. This study investigates heatwaveresilient architecture, particularly where air conditioning is unavailable and cooling relies on passive strategies. Numerous simulations were conducted on a simplified building model using future-updated weather data and a parametric approach. This method enabled a detailed exploration of the effects of specific parameters (One-at-a-time Sensitivity Analysis) on thermal comfort during early design stages. The results suggest that buildings without mechanical air conditioning will struggle to maintain thermal comfort. The most influential parameters were window shading style, solar heat gain coefficient, and window-to-wall ratio. The main contribution of this study is developing a highly applicable model for a medium-sized residential building and a sensitivity analysis of thermal comfort during heatwaves, considering key geometric and physical parameters.
Building Resilience to Heatwaves : Parametric Simulation Approach Aiding Passive Design Strategies for Thermal Comfort in Future Climate
Dalach, Agata (Autor:in) / TUHH Universitätsbibliothek (Gastgebende Institution)
2024
Aufsatz (Konferenz)
Elektronische Ressource
Englisch
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