Convective heat transfer in domed skylight cavities

Abstract

Domed skylights are important architectural design elements that deliver daylight and solar heat into buildings, and connect the building's occupants to the outdoor environment. Despite the widespread use of domed skylights, there is limited information on the convective heat transfer within cavities of multi-glazed domes. This information is required to evaluate the thermal performance of domed skylights for product rating purposes, or to evaluate the heat loss or gain of installed skylights in buildings. This article presents a numerical study on the laminar natural convection in horizontal concentric domed cavities heated from the inside surface. A commercial CFD package is used to solve for the flow and temperature fields. The results show that for large cavity gap spacing-to-radius ratios, the cavity flow is mono-cellular and steady state. For small gap spacing ratios, however, the cavity flow may be multi-cellular and transient periodic. Practical correlations for the heat transfer coefficient as a function of the cavity shape and gap spacing ratio are developed for both flow regimes. The critical gap spacing ratio that yields the maximum Nusselt number is quantified for each cavity shape.

Keywords:

• natural laminar convection
• domed cavity
• domed skylight
• glazing

Acknowledgements

This work was funded by the Natural Sciences and Engineering Research Council (NSERC), the National Research Council of Canada (NRC), the Panel for Energy Research and Development (PERD), British Columbia Hydro, and Natural Resources of Canada (NRCan). The authors are very thankful for their financial support.