"Soft coat" low-e coatings are applied to the glass at lower temperatures and even thinner thicknesses than hard coatings. Both types of low-e coatings (within insulated glazing assemblies) are typically warranted for 10 to 50 years.
The only spectrally selective coatings now available are modified soft coat low-e coatings. The selective properties of the coatings are determined by modifying the coating's thickness and number of layers. A spectrally selective tinted glazing with a pyrolytic hard coat serves a similar purpose. These spectrally selective hard coats are currently under development.
"Aftermarket" films are available for application on existing windows. They are relatively easy to apply on glazing up 36 square inches (91.5 square centimeters). They are often applied to the glass with a water soluble adhesive. To reduce the possibility of bubbles and wrinkles on large windows, have the film installed professionally. Most films should be applied to the inside surface of the glass since they can be damaged easily by weather. If you plan to install the film yourself, be careful to select the appropriate film for your needs, and understand all directions before beginning. Plastic films generally last about 8 to 10 years before they start looking worn.
Performance Selection
The key measures of window performance are the U-Factor, Solar Heat Gain Coefficient, and Visible Transmittance. The air leakage rating (measure of the rate of air loss around a window under a specific pressure differential) is also important, but not addressed here.
The U-Factor is a measure of how easily heat travels through a material. The lower the value, the lower the amount of heat transfer through the window (from the interior to the exterior). Some manufacturers rate thermal performance using R-Factors. R-Factor is the inverse of the U-Factor, i.e., 1/U = R, 1/R = U. For example: a U-Factor of 0.25 is the same as an R-Factor of 4.0. The overall or "total" or "whole window" U-Factor of any window depends on the type of glazing, frame materials and size, glazing coatings, and type of gas (air, or inert argon or krypton) between the panes. Some typical U-Factor ranges for different window assemblies are: - Single glazed: 0.91 - 1.11
- Double glazed: 0.43 - 0.57
- Triple glazed: 0.15 - 0.33
The Solar Heat Gain Coefficient (SHGC) is the fraction of solar heat that enters the window and becomes heat. This includes both directly transmitted and absorbed solar radiation. The lower the SHGC, the less solar heat that the window transmits through the glazing from the exterior to the interior, and the greater its shading ability. In general, South facing windows in houses designed for passive solar heating (with a roof overhang to shade them in the summer) should have windows with high a SHGC to allow in beneficial solar heat gain in the winter. East or West facing windows that get a lot of undesirable sun in mornings and afternoons, and windows in houses in hot climates, should have lower SHGC assemblies.
The visible transmittance (VT) refers to the percentage of the visible spectrum (380-720 nanometers) that is transmitted through the glazing. When daylight in a space is desirable, as in showrooms and studios, high VT glazing is a logical choice. However, low VT glazing such as bronze, gray, or reflective-film windows are more logical for office buildings or where reducing interior glare is desirable. A typical clear, single-pane window has a VT of 0.90, meaning it admits 90% of the visible light.
The ratio between SHGC and VT is called the light-to-solar gain ratio (LSG.) This provides a gauge of the relative efficiency of different glass types in transmitting daylight while blocking heat gains. The higher the ratio number the brighter the room is without adding excessive amounts of heat.
Here are typical values for the Total Window and Center of Glass ( ) for different types of windows:
| Window and Glazing Types | SHG | VT | LSG | | Single-glazed, clear | 0.79 (0.86) | 0.69 (0.90) | 0.87 (1.04) | | Double-glazed, clear | 0.58 (0.76) | 0.57 (0.81) | 0.98 (1.07) | | Double-glazed, bronze | 0.48 (0.62) | 0.43 (0.61) | 0.89 (0.98) | | Double-glazed, spectrally selective | 0.31 (0.41) | 0.51 (0.72) | 1.65 (1.75) | | Double-glazed, spectrally selective | 0.26 (0.32) | 0.31 (0.44) | 1.19 (1.38) | | Triple-glazed, new low-e | 0.37 (0.49) | 0.48 (0.68) | 1.29 (1.39) |
Factors to consider when choosing windows are: climate, building design, building orientation, and external shading. Check with manufacturers for product specifications.
Calculating Energy Savings
Energy savings from solar control glazing are difficult to accurately predict. Predictions of savings are based on many variables such as: size and orientation of the windows, solar heat gain coefficient (SHGC), and the cooling load factor (CLF; the ratio of actual total cooling compared with total steady-state cooling during the same period at constant ambient conditions.) To make this somewhat simpler, some references combine these variables into one figure: the Heat Transfer Multiplier (HTM). The HTM will vary with location, seasonal changes, time of day, shading, orientation, temperature, and building color.
There are also computer programs for sizing of heating/cooling systems. These can also be used to estimate solar heat gain from different types of windows (given the SHGC and climate). Typically, you run the same program for each choice in window type and find the dollar value of the difference in energy saved between the choices. You can then divide the purchase price by the estimated savings to determine simple payback.
Some solar control films are very costly and may have very long payback periods. In such cases it may make better sense to consider other shading devices such as awnings, overhangs, solar screens, shutters, roller shades, blinds, and draperies.
|
Related Articles
Related Tips
Related Videos
