Experimental and numerical study of heat transfer from a window with an internal Venetian blind

•Airflow characteristics of non-closed cavity were investigated by experiment and CFD.•The airflow rates in the cavity were not significantly affected by the blind slat angle.•The convective heat transfers from surface was unaffected by the slat angle.•The method to estimate the heat transfer by ven...

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Bibliographic Details
Published in:Energy and buildings 2020-09, Vol.223, p.110128, Article 110128
Main Authors: Nishikawa, Sachiko, Gomi, Isamu, Katsumata, Shun, Kamata, Hiroya, Nagata, Akihiro, Kinoshita, Taito, Sakuma, Eiji
Format: Article
Language:English
Subjects:
Air flow
Computational fluid dynamics
Convective heat transfer
Convective heat transfer coefficients
Experiments
Glass
Glazing
Heat transfer
Heating
Knowledge management
Shading
Shading devices
Solar heat gain
Surface temperature
Temperature
Temperature gradients
Temperature requirements
Venetian blind
Ventilation
Window
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Summary:•Airflow characteristics of non-closed cavity were investigated by experiment and CFD.•The airflow rates in the cavity were not significantly affected by the blind slat angle.•The convective heat transfers from surface was unaffected by the slat angle.•The method to estimate the heat transfer by ventilation is presented. For windows with internal shading devices, accurate calculations of the thermal transmittance, solar heat gain, and window surface temperature require knowledge of the heat transfer by ventilation between the room and the unclosed cavity formed between the glazing surface and the shading devices. In this study, experiments and numerical analyses (CFD) were conducted to evaluate the effects of the blind slat angle and temperature difference pattern on the airflow characteristics and heat transfer. For the airflow rates near the glass surface and the blind surface in the cavity, the airflow rates were larger as the temperature difference increased but were not significantly affected by the blind slat angle in neither experiment nor CFD. Comparing the results between the heat transfer of the experiment and CFD, the CFD trend was in line with that of the experiment. The convective heat transfer from the glass and the blind seemed to be unaffected by the slat angle. The method to estimate the heat transfer by ventilation from the unclosed cavity to the room, presented in this study, seemed to be viable. These results provide fundamental knowledge regarding window energy and surface temperature calculations for the models that have spacing between glass to shading more than 100 mm.
ISSN:0378-7788
1872-6178
DOI:10.1016/j.enbuild.2020.110128