Indoor Thermal Environment in Different Generations of Naturally Ventilated Public Residential Buildings in Singapore

This study aims to evaluate and compare the indoor air velocities and thermal environment inside different generations of public residential buildings developed by the Housing and Development Board (HDB) of Singapore and analyze the impact of façade design on the indoor thermal environment. To achie...

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Bibliographic Details
Published inAtmosphere Vol. 13; no. 12; p. 2118
Main Authors Deng, Ji-Yu, Wong, Nyuk Hien, Hii, Daniel Jun Chung, Yu, Zhongqi, Tan, Erna, Zhen, Meng, Tong, Shanshan
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.12.2022
Subjects
Air temperature
Analysis
Building design
Buildings
Climatic conditions
Computational fluid dynamics
Computer applications
Condominiums
Design
Dwellings
Energy consumption
Energy efficiency
Environmental aspects
Facades
Fluid dynamics
Green buildings
Heating, cooling and ventilation
High temperature
Housing
Housing policy
Humidity
Hydrodynamics
Impact analysis
Indoor air
Indoor air quality
Indoor environments
Literature reviews
natural ventilation
Public buildings
Public housing
Residential areas
residential building
Residential buildings
Software
Thermal comfort
thermal environment
Thermal environments
Tropical climates
Tropical environment
Tropical environments
Ventilation
Wind
Wind speed
Wind velocities
window-to-wall ratio
Singapore
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Summary:This study aims to evaluate and compare the indoor air velocities and thermal environment inside different generations of public residential buildings developed by the Housing and Development Board (HDB) of Singapore and analyze the impact of façade design on the indoor thermal environment. To achieve this goal, several case studies were carried out, namely, five typical HDB blocks built in different generations from the 1970s to recent years. Firstly, these five blocks with different façade design features were simulated to obtain the indoor air temperatures for both window-closed and window-open scenarios by using the EnergyPlus V22.2.0 (U.S. Department of Energy) and Design-Builder v6 software(DesignBuilder Software Ltd, Stroud, Gloucs, UK). Meanwhile, the computational fluid dynamics (CFD) simulations were conducted to obtain the area-weighted wind velocities in the corresponding zones to evaluate the indoor thermal comfort. Accordingly, the effects of façade design on indoor air temperatures under both the window-closed and window-open conditions were compared and analyzed. Positive correlations between the facades’ window-to-wall ratio (WWR) and the residential envelope transmittance value (RETV) and Ta were confirmed with statistical significance at a 0.05 level. Furthermore, the indoor thermal comfort based on the wind open scenarios was also investigated. The results indicate that the thermal environment can be greatly improved by implementing proper façade design strategies as well as opening the windows, which could result in an average 3.2 °C reduction in Ta. Finally, some principles were proposed for the façade design of residential buildings in tropical regions with similar climate conditions.
ISSN:2073-4433
2073-4433
DOI:10.3390/atmos13122118