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Ductwork system
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The goal of an effective ductwork system is to provide constant temperature
and humidity control throughout the house without noticeable air stratification
or noise. The best way to accomplish this is with a simple, direct duct design,
which ensures both good performance and low cost.
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Go to:
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Types of Ductwork Systems
Three types of ductwork systems are common in the U.S.:
- flexible (the most common type in Texas)
Flexible duct systems consist of insulated flexible duct connected with
metal transitions and joint connections. This system is used for attic
installations where flexible duct can be suspended over the joist and whenever
crawl-space installations are possible. This design works best with centrally
located air conditioning systems.
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Sizing
A properly sized and installed air distribution system is as important as
properly sized and installed heating, ventilation and air conditioning (HVAC)
equipment.
When designing an air distribution system, you should consider:
- capacity of the HVAC unit
- quantity of air supplied to each individual room
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Design and Insulation
A ductwork system that is not properly designed, installed, insulated and
sealed can increase total heating and cooling costs up to 40% and may decrease
the comfort, health and safety of your home.
Different rooms need different volumes of air to maintain even temperatures
throughout your home. Duct sizes that are not properly matched with room sizes
cause hot and cold spots in a house. Long duct runs — the length the duct
travels from the air handler (typically located in the attic) to the room — can
raise the temperature of cooled air and lower the temperature of heated air
before it reaches the room. This same temperature loss occurs when ducts run
through unconditioned spaces, such as attics.
Placement of ducts can’t always be controlled in the design of most houses;
however, any ill effects can be minimized with good duct insulation. Ducts are
typically located in the attic. If they’re poorly insulated, the oven-like
temperatures during the summer tend to transfer into the ducts, which heats up
the cool air from the air conditioner before it gets into the living space. In
winter, the opposite occurs. The warm air from the furnace loses heat to the
surrounding cooler air in the attic, which makes the equipment work harder.
Energy costs increase and the comfort level of your home decreases.
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Recommended Duct Design
Good duct design includes thermal efficiency achieved with adequate
insulation and airtight seals. We recommend ducts insulated to an R-Value of
R-6. Ductwork should be kept as straight as possible. Any turns, bends or ‘S’
loops will cause additional pressure loss and reduced airflow.
Duct insulation should have a vapor barrier on the outer surface to prevent
moisture in ambient air from passing through the insulation and condensing on
the duct surfaces. Condensation will cause the insulation to be saturated with
water, destroying its insulating ability and deteriorating the duct
material.
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Properly Sealing an Air Distribution System
- All air duct transitions, joints and connections (including where duct
attaches to supply boot) should be sealed airtight using a UL 181 approved
mastic sealant or a UL 181-approved mastic tape.
- All seams on air handlers, furnaces and plenums should be sealed with
mastic and reinforced with fiberglass mesh tape or UL 181 tape, or sealed with
UL 181-approved mastic tape. Do not block combustion air passages on fossil
fuel furnaces. Mastic alone is acceptable on unit access panels.
- If using duct board, all seams should be sealed with mastic on the foil
side reinforced with fiberglass mesh tape or UL 181 tape or sealed with UL
181-approved mastic tape. Duct board should be used within a return chase,
turned foil side in.
- Return air chases should be sealed with mastic at the sole plate and top
plate and at all corner joints and seams. The preferred method of return air
design is a ducted return. Avoid using building cavities for the return duct
chase. If building cavities are used as return air duct, duct chase should be
extended into the attic or between floors so that the section penetrating the
floor joist or ceiling is continuous to prevent leakage.
- Mastic sealant utilized should be water-based, non-toxic and consist of at
least 50% solids and be UL 181 approved.
- Mastic or mastic tape should be applied according to manufacturer’s
specifications.
- All plastic or nylon tie straps used for securing flex duct should be
installed with a duct tie tool.
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Frequently Asked Questions:
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Take the ENERGY STAR home tour
 |
Take a room-by-room tour of ENERGY STAR @ home and learn what you can do to save energy, money and help protect the environment.
|
| |
| | |
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| |
Budgeting made easy
Sign up for Average Billing to eliminate high summertime bills.
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| |
Be Secure
With Secure Plan, you can rely on one low, fixed rate throughout the term of your plan.
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Ductwork system
|
|
|
The goal of an effective ductwork system is to provide constant temperature
and humidity control throughout the house without noticeable air stratification
or noise. The best way to accomplish this is with a simple, direct duct design,
which ensures both good performance and low cost.
|
|
Go to:
|
|
Types of Ductwork Systems
Three types of ductwork systems are common in the U.S.:
- flexible (the most common type in Texas)
Flexible duct systems consist of insulated flexible duct connected with
metal transitions and joint connections. This system is used for attic
installations where flexible duct can be suspended over the joist and whenever
crawl-space installations are possible. This design works best with centrally
located air conditioning systems.
|
|
Sizing
A properly sized and installed air distribution system is as important as
properly sized and installed heating, ventilation and air conditioning (HVAC)
equipment.
When designing an air distribution system, you should consider:
- capacity of the HVAC unit
- quantity of air supplied to each individual room
|
|
Design and Insulation
A ductwork system that is not properly designed, installed, insulated and
sealed can increase total heating and cooling costs up to 40% and may decrease
the comfort, health and safety of your home.
Different rooms need different volumes of air to maintain even temperatures
throughout your home. Duct sizes that are not properly matched with room sizes
cause hot and cold spots in a house. Long duct runs — the length the duct
travels from the air handler (typically located in the attic) to the room — can
raise the temperature of cooled air and lower the temperature of heated air
before it reaches the room. This same temperature loss occurs when ducts run
through unconditioned spaces, such as attics.
Placement of ducts can’t always be controlled in the design of most houses;
however, any ill effects can be minimized with good duct insulation. Ducts are
typically located in the attic. If they’re poorly insulated, the oven-like
temperatures during the summer tend to transfer into the ducts, which heats up
the cool air from the air conditioner before it gets into the living space. In
winter, the opposite occurs. The warm air from the furnace loses heat to the
surrounding cooler air in the attic, which makes the equipment work harder.
Energy costs increase and the comfort level of your home decreases.
|
|
Recommended Duct Design
Good duct design includes thermal efficiency achieved with adequate
insulation and airtight seals. We recommend ducts insulated to an R-Value of
R-6. Ductwork should be kept as straight as possible. Any turns, bends or ‘S’
loops will cause additional pressure loss and reduced airflow.
Duct insulation should have a vapor barrier on the outer surface to prevent
moisture in ambient air from passing through the insulation and condensing on
the duct surfaces. Condensation will cause the insulation to be saturated with
water, destroying its insulating ability and deteriorating the duct
material.
|
|
Properly Sealing an Air Distribution System
- All air duct transitions, joints and connections (including where duct
attaches to supply boot) should be sealed airtight using a UL 181 approved
mastic sealant or a UL 181-approved mastic tape.
- All seams on air handlers, furnaces and plenums should be sealed with
mastic and reinforced with fiberglass mesh tape or UL 181 tape, or sealed with
UL 181-approved mastic tape. Do not block combustion air passages on fossil
fuel furnaces. Mastic alone is acceptable on unit access panels.
- If using duct board, all seams should be sealed with mastic on the foil
side reinforced with fiberglass mesh tape or UL 181 tape or sealed with UL
181-approved mastic tape. Duct board should be used within a return chase,
turned foil side in.
- Return air chases should be sealed with mastic at the sole plate and top
plate and at all corner joints and seams. The preferred method of return air
design is a ducted return. Avoid using building cavities for the return duct
chase. If building cavities are used as return air duct, duct chase should be
extended into the attic or between floors so that the section penetrating the
floor joist or ceiling is continuous to prevent leakage.
- Mastic sealant utilized should be water-based, non-toxic and consist of at
least 50% solids and be UL 181 approved.
- Mastic or mastic tape should be applied according to manufacturer’s
specifications.
- All plastic or nylon tie straps used for securing flex duct should be
installed with a duct tie tool.
|
|
|
|
|
Frequently Asked Questions:
|
|
|
|
| | |
|
Take the ENERGY STAR home tour
|
Take a room-by-room tour of ENERGY STAR @ home and learn what you can do to save energy, money and help protect the environment.
|
| |
| | |
|
|
|
| |
Budgeting made easy
Sign up for Average Billing to eliminate high summertime bills.
|
|
|
|
|
| |
Be Secure
With Secure Plan, you can rely on one low, fixed rate throughout the term of your plan.
|
|
|
|
|
|
|
|
|
