Listed below are a number of national conferences which offer an excellent opportunity to keep abreast of the latest technologies, programs and strategies.
Affordable Comfort Conference Contact: Affordable Comfort, Inc. Phone: 800-344-4866 or 724-627-5200 Fax: 724-627-5226 www.AffordableComfort.org
ACEEE Summer Study on Energy Efficiency in Buildings Contact: American Council for an Energy Efficient Economy Phone: 202-429-0063 Fax: 202-429-0193 www.aceee.org
Better Buildings: Beter Business Conference (Wisconsin and Illinois) Contact: The Energy Center of Wisconsin www.ecw.org
Comfortech National Residential HVAC Seminar and Comfort Technology Showcase Contact: Contracting Business Phone: 800-467-0997 hvaccomfortech.com
Construction Business & Technology Conference & Expo Contact: Journal of Light Construction Phone: 800-375-5981 www.jlconline.com
Energy Efficient Builders Association (EEBA) Conference and Expo Contact: Energy & Environmental Building Association, Inc. Phone: 612-851-9940 Fax: 612-851-9507 www.eeba.org
Performance of the Exterior Envelopes of Whole Buildings Contact: Oak Ridge National Laboratory www.ornl.gov/buildings/2010
RESNET Building Performance Conference Phone: 760-806-3448 www.resnet.us
A Pascal is small metric unit of pressure. One Pascal is approximately 0.004 inches of water column. Commonly used airtightness test pressures of 25 and 50 Pascals are approximately 0.10 … Read more
Environmental conditions affect readings by varying amounts depending on the type of conditions that exist. The article below may help you with understanding how each of the different conditions can affect your readings.
We recommend DG-700 and DG-500 pressure gauges be recalibrated once every two years. Blower Door and Duct Blaster fans do not need recalibration unless testing requirements mandate a calibrated fan.
A standard airtightness test of a house can usually be completed in 30 minutes or less. Once you arrive at a house, the Blower Door can typically be installed in … Read more
For years, technicians have been using a simple Blower Door comparison test to estimate residential duct leakage to the outside. The technique, called Blower Door subtraction, involves conducting two whole house Blower Door airtightness tests with and without the supply and return registers and grills sealed off from the house. A subtraction of the sealed register test from the unsealed register test provides an estimate of duct leakage to the outside.
Researchers now realize that the Blower Door subtraction test has a number of drawbacks with respect to the accuracy of test results. Accuracy is reduced for two reasons. First, subtraction will typically underestimate duct leakage due to connections between the duct system and the interior of the house which are not sealed when the registers and grills are temporarily sealed. The Blower Door subtraction method assumes that once the registers and grills are taped off, the duct system is effectively outside of the pressure envelope of the house, and as a result the Blower Door does not measure any duct leakage in that configuration. However, connections between the duct system and the interior of the house cause a certain amount of duct leakage to be measured even with the duct system sealed from the house. The amount of underestimation due to this phenomenon is a function of how well the duct system is connected to the structure of the house.
Secondly, because Blower Door Subtraction involves subtraction of two separate Blower Door test results (using the same Blower Door), the accuracy of the test result is a function of the repeatability of the Blower Door measurements. The error due to repeatability further clouds the accuracy of your subtraction test. So now that we know there are shortcomings to Blower Door subtraction, is there anyway to improve our leakage estimate using the subtraction technique?
There is a technique to alleviate the underestimation problem associated with Blower Door subtraction. The subtraction duct leakage estimate can be modified by taking one additional pressure measurement. The pressure measurement needed is the pressure between the duct system and the house with the registers and grills sealed and the Blower Door depressurizing (or pressurizing) the house to the target pressure of 50 Pa. This measurement can be taken at the supply or return plenum, or at a supply register or return grill by punching a small hole through the masking tape and inserting a pressure tap or hose connected to a pressure gauge. Once this pressure is measured, an appropriate subtraction correction factor can be used to modify your original subtraction duct leakage estimate. A table of correction factors for Blower Door subtraction is shown below.
House to Duct Pressure in Pascals (taped off)
Subtraction Correction Factor (SCF)
50
1.00
49
1.09
48
1.14
47
1.19
46
1.24
45
1.29
44
1.34
43
1.39
42
1.44
41
1.49
40
1.54
38
1.65
36
1.78
34
1.91
32
2.06
30
2.23
28
2.42
26
2.64
24
2.89
22
3.18
Let’s look at an example to illustrate use of the subtraction correction factor (SCF). You have performed a subtraction test and found the following:
CFM50 (ducts open) = 3,250 *
CFM50 (ducts sealed) = 2,825 *
Pressure between the ducts and the house (ducts sealed) = 40 Pa
* If ducts run through attics or crawlspaces, be sure the attic or crawlspace is effectively outside when the blower door is operating – i.e. attic to outside pressure=0.
In this case, our modified duct leakage estimate is 54 percent larger that the original Blower Door subtraction estimate. This means we would have underestimated duct leakage to the outside by 54 percent without using the correction factor.
Now how about repeatability error. On a day with only slight wind, our experience is that the repeatability of manual Blower Door test is about +/- 3% of the unsealed whole house CFM50 value when using the same gauges for both tests. For the example above, a repeatability error of 3% means we have an error of approximately +/- 97 CFM50 (0.03 x ,3250 CFM50) in our leakage estimate. But we must also apply the correction factor calculated above to the 97 CFM50 which increases the error to +/- 149 CFM50 (97 CFM50 x 1.54). Thus our final subtraction leakage result is 655 CFM50 (+/- 149 CFM50). This means the actual leakage in the duct system is somewhere between 506 CFM50 and 804 CFM50. And in very windy weather, repeatability error will increase much larger than the 3% shown here.
Note: If you are using an APT system to conduct your Blower Door test, repeatability errors will typically be reduced below the 3% quoted above, and the APT system will provide you with a estimate of the measurement uncertainty.
Do all of these problems mean that I shouldn’t be using the subtraction method to estimate duct leakage? Not at all. If you need to quantify duct leakage and are comfortable with the relative imprecision of the subtraction technique, subtraction makes good sense. Of course you should always use the correction factors listed in the table above when using the subtraction method, to account for underestimation. If accuracy is important, much greater precision of duct leakage estimates can be achieved by using the Minneapolis Duct Blaster and directly testing the duct system.
And a final word of caution when using the subtraction method, if the measured duct to house pressure is less than about 20 Pa (meaning the duct system is very well connected to the house structure), we suggest that Blower Door subtraction (modified or not) can not be relied upon to provide meaningful duct leakage estimates. This commonly means that Blower Door subtraction can not be used in houses which use building cavities for a significant part of the duct system (e.g. basement houses which use panned under ceiling joists for return ducts). In these cases, the duct system must be tested directly with a Duct Blaster.
In applications where a duct leakage estimate is not needed at all, use of a blower door and a pressure pan is probably the ideal setup. In this case, duct leakage can be quickly checked by depressurizing the house to 50 Pa and taking a quick pressure pan reading at each register or grill. Inspection standards can also be set using this procedure. For example, the duct system might pass inspection if all registers and grills have a pressure pan reading of 1 Pa or less. This technique provides crews and inspectors with excellent measurement feed-back, but simply does not quantify the leakage in the system.
Once the leakage rate for a building has been measured, it is useful to estimate the cumulative size (in square inches) of all leaks or holes in the building’s air barrier. The estimated leakage area provides us with a way to visualize the physical size of the measured holes in the building. This can be particularly important when explaining the results of a test to a building owner. Leakage area calculations are also used in infiltration models to estimate the building’s natural air change rate (i.e. the air change rate under natural weather conditions).
TEC’s airtightness test analysis software calculates two separate leakage areas, based on differing assumptions about the physical shape of the hole. These leakage area calculations are compatible with the two most commonly used infiltration models. Energy analysis or rating software that require the user to input airtightness test results typically specify one of these two leakage areas.
The Equivalent Leakage Area (EqLA) is defined by Canadian researchers at the Canadian National Research Council as the area of a sharp edged orifice (a sharp round hole cut in a thin plate) that would leak the same amount of air as the building does at a pressure of 10 Pascals. The EqLA is used in the AIM infiltration model.
Effective Leakage Area (ELA) was developed by Lawrence Berkeley Laboratory (LBL) and is used in their infiltration model. The Effective Leakage Area is defined as the area of a special nozzle-shaped hole (similar to the inlet of your blower door fan) that would leak the same amount of air as the building does at a pressure of 4 Pascals.
Importantly, when using leakage area calculations to demonstrate physical changes in building airtightness, we recommend using the Canadian EqLA measurement. Typically, EqLA more closely approximates physical changes in building airtightness. For example, if you performed a blower door test, and then opened a window to create a 25 square inch hole and repeated the test, the estimated EqLA for the building will have increased by approximately 25 square inches from the initial test result. The EqLA is also easier to measure, especially in windy weather, because the measurement is taken at a higher building pressure than the ELA.
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