The following is a guest post by our good friend Miles Dyson of Inspection Connection. Miles is one of Las Cruces, New Mexico’s foremost experts in home inspection, energy rating, and green certification.
Quality light from the sun is prized in modern home design. Well-placed windows and skylights bring healthy day lighting to interior spaces. Properly located glazing insures we can work, study and play – taking full advantage of every room. Without careful planning, quality day lighting often comes at a significant cost to the comfort and efficiency of a home.
Skylights are the most common device used to get light where we need it in our homes after traditional window units. The configuration and installation of skylights satisfy light requirements as intended, but can cause big problems for home comfort and energy efficiency.
The dual plastic lens, metal-framed sky light is the most common installation used in our area for through-the-roof day lighting.
Most newer homes have insulation installed at the ceiling with a thermal resistance value of at least R-30. Heat energy moves from areas of higher concentration to areas of lower concentration. Insulation works as a barrier between areas of heat and cold. The aver age insulating value of a plastic skylight is between R-0.5 and 1.5, which is one-thirtieth the thermal protection of the surrounding insulated ceiling area!
Open attic space between the roof deck and the ceiling of our rooms must be spanned to get the desired sunlight to our living space.
This requires construction of a wood framed, sheetrocked skylight well. The short wall sec tions of this well area have the conditioned space of the home on one side and the harsh air temperatures of the attic space on the other.
In most skylight installations, these wall sections are either poorly insulated or do not get insulated at all. Heat rises into these wells and finds a large surface area in addition to the skylight where thermal resistance is minimal. For the most part, we do a great job of insulating the ceiling of a home, then cut gaping holes in that highly insulated structure (even small skylights are typically 4 square feet and include 20 or more square feet of poorly insulated well wall).
The ceiling plane is the most critical com ponent in the thermal envelope of any home.
Heat rises against the ceiling in winter. With a poor thermal barrier at skylight assemblies, heat energy is radiated to the cold space outside.
In the summer, radiant heat energy blasts into the conditioned space through these ar eas, hardly deterred by the meager insulating value afforded by most skylight and well wall installations. Air infiltration compounds the efficiency and comfort problems.
In the winter, if warm air can move through the ceiling plane, it is replaced by cold air pulled in at other infiltration points lower in the conditioned envelope of the home. As you may have guessed, skylight installations are not generally airtight. In fact, blower door infiltration testing I have con ducted on new and existing homes shows that a large percent of air movement in and out of homes comes through skylight assemblies.
This is not to blame on the skylight unit itself, but on the method of installation.
Typical skylights attach to a wood frame curve at the top of a well wall adjacent to the roof deck. Most have gaps large enough to stick a finger through leading either to the attic space or the outside at the connection to the roof and well walls. Think of having a window cracked open a half an inch or so and think how much air would move through that space. Now consider how many skylights are installed in most homes!
Careful consideration should be given to where and how often skylights are installed at the ceiling plane. Overuse will exacerbate the problems described above.
When skylights are installed they should be the best quality that the project budget will allow. Better quality skylights (look for Energy Star-rated) will have higher thermal resistance and will come with gaskets and instructions to provide a tight air barrier.
The framed skylight wall well area should be insulated as well as or better than the regular walls of the home. Insulation at the framed wall wells should include a solid air barrier surface on the attic side of the insula tion to prevent air movement through porous fiberglass or cellulose or be lined with rigid board or spray foam insulation.
In rooms with high ceilings, consider clerestory windows installed at north or south facing walls. Windows tend to have better thermal properties than skylights, are easier to air seal and do not penetrate the important ceiling plane of the home envelope.
Solar tubes offer a design option that limits the heat transfer and air infiltration problems inherent to standard skylight instal lations. Solar tubes are round, sealed, highly reflective tubes that bring light from a roof mounted collector through the attic space and into interior rooms. The smaller footprint of the collector and surface area of the light tube make it easier to insulate and limit radiant heat transfer. These units are available with an integral electric fixture that allows the solar tube to double as a light source after the sun has set.
Be sure to consider your comfort and future utility bills when considering your sky light options. Good planning will allow you to have good interior day lighting and energy efficiency.
For more information on green and efficient homes, visit www.icenergyrate.com
Miles Dyson is the owner of Inspection Connection LC – Professional Home Energy Rating and Home Inspection Services in Mesilla Park and can be reached at 202-2457. Dyson is a RESNET certified Home Energy Rater and ASHI certified Home Inspector.
Contact Picacho Mountain today at 575-523-2500 for more information on building your energy-efficient, green home in Las Cruces, New Mexico. Custom Estate Homes, Patio Homes, Town Homes, and Neighborhood Retail.