While skylights are desirable for their ability to bring light into otherwise dark interiors, they also function as rooftop solar collectors and hinder the ability of cool roof technology to help reduce air conditioning operating costs. If the daylighting benefit is to outweigh the negative impact on the overall energy performance of a cool roof, skylights need to maximize visible light transmission while minimizing solar heat gain.
Equally important is a skylight’s ability to insulate against heat transfer caused by both conduction and convection. The basic construction of typical dual-pane insulating glass—low-e coated glass and clear glass separated by a warm-edge spacer and filled with an inert gas to create an insulating cavity—does a good job of reducing both conductive and convective heat transfer in vertically mounted windows. However, when this dual-pane (or single-cavity) insulating glass is mounted toward the horizontal, as in a typical skylight, it can lose up to 40% of its ability to insulate against convective heat transfer, a direct result of shortening the convective airflow paths.
This means that in the evening and winter, more heat in a church building escapes through a sloped skylight than it does through a vertical window using comparable insulating glass. And during the day, more outdoor ambient heat passes into a church through the glass in a skylight than through similar glass in a window.
Since the energy conservation performance of skylights is primarily a function of the glass, the best way to maximize the energy efficiency of a cool roof is to create a second insulating cavity to reduce convective heat transfer. Triple-pane insulating glass can accomplish this but, unfortunately, is often too heavy to safely mount overhead, particularly for larger skylights. An ideal solution is suspended film insulating glass, in which one or more heat-reflective coated films are suspended within the glass unit to create multiple insulating cavities at no additional weight. Such lightweight glass maintains a high R-value (resistance to heat flow); a low shading coefficient (amount of solar heat radiating through the glass); and a high visible light transmission.
In addition, the suspended film practically eliminates ultraviolet radiation that can cause fading, and because the film is clear and colorless, it maintains visual clarity and normal color rendition. Clearly, film-based multi-cavity insulating glass is tomorrow’s state-of-the-art skylight, window and door glass available today. It has been saving energy in St. Gabriel’s church in Toronto, Ontario.