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Elements of an Energy Efficient House
Some designs are more
expensive to build than
others, but none of them
need to be extremely
expensive to construct.
Recent technological
improvements in building
elements and
construction
techniques, and heating,
ventilation, and cooling
systems, allow most
modern energy saving
ideas to be seamlessly
integrated into any type
of house design without
sacrificing comfort,
health, or aesthetics.
The following is a
discussion of the major
elements of
energy-efficient home
design and construction
systems.
The Thermal
Envelope
A "thermal envelope" is everything about the house that serves to shield the living space from the outdoors. It includes the wall and roof assemblies, insulation, windows, doors, finishes, weather-stripping, and air/vapor retarders. Specific items to consider in these areas are described below.
Wall and Roof
Assemblies
There are several alternatives to the conventional "stick" (wood stud) framed wall and roof construction now available and growing in popularity. They include:
Insulation
An energy-efficient house has much higher insulation R-values than required by most local building codes. For example, a typical house in New York State might have haphazardly installed R-11 fiberglass insulation in the exterior walls and R-19 in the ceiling, and the floors and foundation walls may not be insulated. A similar, but well-designed and constructed house's insulation levels would be in the range of R-20 to R-30 in the walls (including the foundation) and R-50 and R-70 in the ceilings. Carefully applied fiberglass batt or roll, wet-spray cellulose, or foam insulations will fill wall cavities completely.
Air / Vapor
Retarders
These are two things that sometimes can do the same job. How to design and install them depends a great deal on the climate and what method of construction is chosen. No matter where you are building, water vapor condensation is a major threat to the structure of a house. In cold climates, pressure differences can drive warm, moist indoor air into exterior walls and attics. It condenses as it cools. The same can be said for very Southern climates, just in reverse. As the humid outdoor air enters the walls to find cooler wall cavities it condenses into liquid water. This is the main reason why some of the old buildings in the South that have been retrofitted with air conditioners now have mold and rotten wood problems.
Regardless of your
climate, it is important
to minimize water vapor
migration by using a
carefully designed
thermal envelope and
sound construction
practices. Any water
vapor that does manage
to get into the walls or
attics must be allowed
to get out again. Some
construction methods and
climates lend themselves
to allowing the vapor to
flow towards the
outdoors. Others are
better suited to letting
it flow towards the
interior so that the
house ventilation system
can deal with it.
The Airtight Drywall
Approach and the Simple
CS system are other
methods to control air
and water vapor movement
in a residential
building. These systems
rely on the nearly
airtight installation of
sheet materials such as
drywall or gypsum board
on the interior as the
main barrier, and
carefully sealed foam
board and/or plywood on
the exterior.
Foundations and
Slabs
Foundation walls and slabs should be at least as well insulated as the living space walls. Uninsulated foundations have a negative impact on home energy use and comfort, especially if the family uses the lower parts of the house as a living space. Also, appliances that supply heat as a by-product, such as domestic hot water heaters, washers, dryers, and freezers, are often located in basements. By carefully insulating the foundation walls and floor of the basement, these appliances can assist in the heating of the house.
Windows
The typical home loses over 25% of its heat through windows. Since even modern windows insulate less than a wall, in general an energy-efficient home in heating dominated climates should have few windows on the north, east, and west exposures. A rule-of-thumb is that window area should not exceed 8-9% of the floor area, unless your designer is experienced in passive solar techniques. If this is the case, then increasing window area on the southern side of the house to about 12% of the floor area is recommended. In cooling dominated climates, its important to select east, west, and south facing windows with low solar heat gain coefficients (these block solar heat gain). A properly designed roof overhang for south-facing windows is important to avoid overheating in the summer in most areas of the continental United States. At the very least, Energy Star rated windows or their equivalents, should be specified according to the Energy Star regional climatic guidelines.
In general, the best
sealing windows are
awning and casement
styles since these often
close tighter than
sliding types. Metal
window frames should be
avoided, especially in
cold climates. Always
seal the wall air/vapor
diffusion retarder
tightly around the edges
of the window frame to
prevent air and water
vapor from entering the
wall cavities.
Air-Sealing
A well-constructed thermal envelope requires that insulating and sealing be precise and thorough. Sealing air leaks everywhere in the thermal envelope reduces energy loss significantly. Good air-sealing alone may reduce utility costs by as much as 50% when compared to other houses of the same type and age. Homes built in this way are so energy-efficient that specifying the correct sizing heating/ cooling system can be tricky. Rules-of-thumb system sizing is often inaccurate, resulting in oversizing and wasteful operation.
Controlled Ventilation
Since an energy-efficient home is tightly sealed, it's also important and fairly simple to deliberately ventilate the building in a controlled way. Controlled, mechanical ventilation of the building reduces air moisture infiltration and thus the health risks from indoor air pollutants, promotes a more comfortable atmosphere, and reduces the likelihood of structural damage from excessive moisture accumulation.
A carefully engineered
ventilation system is
important for other
reasons too. Since
devices such as
furnaces, water heaters,
clothes dryers, and
bathroom and kitchen
exhaust fans exhaust air
from the house, it's
easier to depressurize a
tight house if all else
is ignored. Natural
draft appliances, such
as water heaters, wood
stoves, and furnaces may
be "back drafted" by
exhaust fans and lead to
a lethal build-up of
toxic gases in the
house. For this reason
it's a good idea to only
use "sealed combustion"
heating appliances
wherever possible and
provide make-up air for
all other appliances
that can pull air out of
the building.
Heat recovery
ventilators (HRV) or
energy recovery
ventilators (ERV) are
growing in use for
controlled ventilation
in tight homes. These
devices salvage about
80% of the energy from
the stale exhaust air
and then deliver that
energy to the fresh
entering air by way of a
heat exchanger inside
the device. They are
generally attached to
the central forced air
system, but they may
have their own duct
system.
Other ventilation
devices such as
through-the-wall and/or
"trickle" vents may be
used in conjunction with
an exhaust fan. They
are, however, more
expensive to operate and
possibly more
uncomfortable to use
since they have no
energy recovery features
to pre-condition the
incoming air.
Uncomfortable incoming
air can be a serious
problem if the house is
in a northern climate,
and they can create
moisture problems in
humid climates. This
sort of ventilation
strategy is recommended
only for very mild to
low humidity climates.
Heating and
Cooling Requirements
Houses incorporating the above elements should require relatively small heating systems (typically less than 50,000 Btu/hour even for very cold climates). Some have nothing more than sunshine as the primary source of heat energy. Common choices for auxiliary heating include radiant in-floor heating from a standard gas-fired water heater, a small boiler, furnace, or electric heat pump. Also, any common appliance that gives off "waste" heat can contribute significantly to the heating requirements for such houses. Masonry, pellet, or wood stoves are also options, but they must be operated carefully to avoid "back drafting."
If an air conditioner is
required, a small (6,000
Btu/ hour) unit can be
sufficient. Some designs
use only a large fan and
the cooler evening air
to cool down the house.
In the morning the house
is closed up and it
stays comfortable until
the next evening.
Beginning a Project
Houses incorporating the above features have many advantages. They feel more comfortable since the additional insulation keeps the interior wall temperatures more stable. The indoor humidity is better controlled, and drafts are reduced. A tightly sealed air/vapor retarder reduces the likelihood of moisture and air seeping through the walls. They are also very quiet because of the extra insulation and tight construction.
There are some potential
drawbacks. They may cost
more and take longer to
build than a
conventional home,
especially if your
builder and the
contractors are not
familiar with them. Even
though their structure
may differ only slightly
from conventional homes,
your builder and the
contractors may be
unwilling to deviate
from what they've always
done before. They may
need education or
training if they have no
experience with these
systems. Because some
systems have thicker
walls than a "typical"
home, they may require a
larger foundation to
provide the same floor
space.
Before beginning a home-building project, carefully evaluate the site and its climate to determine the optimum design and orientation. You may want to take the time to learn how to use some of the energy related software programs that are available to assist you. Prepare a design that accommodates appropriate insulation levels, moisture dynamics, and aesthetics. Decisions regarding appropriate windows, doors, and heating, cooling and ventilating appliances are central to an efficient design. Also evaluate the cost, ease of construction, the builder's limitations, and building code compliance. Some schemes are simple to construct, while others can be extremely complex and thus expensive.
An increasing number of
builders are
participating in the
federal government's
Building America and
Energy Star Homes
programs, which promote
energy-efficient houses.
Many builders
participate so that they
can differentiate
themselves from their
competitors.
Construction costs can
vary significantly
depending on the
materials, construction
techniques, contractor
profit margin,
experience, and the type
of heating, cooling and
ventilation system
chosen. However, the
biggest benefits from
designing and building
an energy-efficient home
are its superior comfort
level and lower
operating costs. This
relates directly to an
increase in its
real-estate market
value.
For the best inspector
in yourneighborhood
visit
www.InspectorLocator.com
or call 1-877 FIND-INS.
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George Timmerman CHI - CMIA* 280 Kemp RD * Suwanee GA 30024 * (770) 495-4870 |