Thermal Break – Energy Efficient Terms
The selection and placement of windows and doors are one of the most important decisions to make when designing your home. Before embarking on the Important journey of choosing windows and doors for your home, it can be helpful to become familiar with some commonly used energy-efficient terms.
Double Glazed Units or Insulated Glass Units (IGUs)
IGUs provide thermal insulation and improved acoustic performance. Consisting of two panes of glass, separated by an Air or Gas filled cavity, an IGU is described in terms of the thickness of the outer pane in millimeters, followed by the cavity width, and finally, the thickness of the internal pane; e.g. 4/12/4. Generally, a 12mm to 15mm cavity width provides optimum performance.
Heat loss and heat gain can occur through leaks in the window or door assembly. Good seals and quality workmanship minimize this.
Panes are assembled from two sheets of glass with an adhesive interlayer. Laminated glass when broken will not shatter or splinter leading to greater safety and security. Laminated glass eliminates nearly 99% of harmful UV rays, reducing fading to floors and furniture.
A specialized interlayer in laminated glass can further reduce Solar Heat Gain Coefficient.
A metallic coating is applied to one side of the glass in order to significantly increase the amount of reflected visible and infra red heat.
A thin coating that is applied to the glass surface to enable it to reflect short wave [direct solar] heat or long wave [re-radiated/reflected] heat. [Learn about Low-E Glass]
The direction of home faces can affect how much energy is used heat and cool. Ideally a home should be oriented north-south to prevent the sun’s rays from penetrating in summer, while still allowing for solar warming in winter. It is impractical for many homes to achieve optimal orientation; however, high performance windows can help achieve a high level of control over a home’s thermal performance.
Passive cooling encourages cooling breezes and air movement in summer as an inexpensive way of cooling your home. Passive cooling is best achieved through: orientation to cooling breezes, increased natural ventilation, a light coloured roof and wall finishes, and appropriate windows and glazing to minimize heat gain.
Passive Solar Heating
Passive solar heating aims to keep the summer sun out while still allowing the winter sun in. As well as using orientation and shading, passive solar heating is best achieved through effective insulation, drought sealing and high performance glazing. Window frames and the type of glazing used play a big part in passive solar heating.
Shading a home can improve comfort and increase energy efficiency. It is important to install effective shading devices to block summer sun from the north while still allowing the lower angled winter sun in.
Solar Control Glass
Glass that reduces heat gain derived from direct solar radiation. This may be achieved via interlayer, body tints, reflective coating or low E coatings.
Solar Heat Gain Coefficient (SHGC)
SHGC is a measure of the amount of solar radiation transmitted through a window and released into the home as heat. The lower a window’s SHGC, the less solar heat in transmits; a low SHGC is vital for warm or hot climates.
Usually green, grey, bronze or blue, toned or tinted glass can shade internal areas and reduces the amount of heat entering through the window. This will keep the building cooler and reduce glare and UV rays.
U Value measures the rate of heat flow through a window, due to temperature difference between the indoor and outdoor environment, taking into account the effect of the frame, glass, seal and any spacers. Heat is lost and gained through a window by the combined effects of conduction, convection and radiation. The lower the U Value, the higher the energy efficiency of the window or door.
Visible Transmittance (VT)
VT is a numeric measure of how much visible light is transferred through the window. The higher the VT, the more daylight that is openly transmitted.