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.More About Radon Mitigation Radon Testing Radon Monitoring
Radon Remediation
When a building (or house) is found to have an elevated level of radon gas (defined by the U.S. Environmental Protection Agency as a radon result of 4.0 pCi/l or higher,) methods of reducing the levels can be applied to cure the problem. The most common method of Radon mitigation (also known as remediation or abatement) is Active Soil Depressurization (ASD.) This method utilizes PVC piping attached to an electric suction fan. The piping typically begins below the lowest floor of the structure's foundation (penetrating the slab of the basement or the plastic membrane of the crawl space) and extends upward to an exit point above ground level. The inline suction fan is mounted in an inconspicuous location on the exterior or within an attic above the home. In cases where the radon fan is installed in the attic, the discharge pipe extends out through the roof so the gas can be released outdoors.
Active (fan assisted) radon mitigation systems can reduce the radon gas entry by as much as 99%. A qualified radon contractor (also known as a radon mitigator or radon remediation specialist) can typically install a mitigation system in a home in less than a day. After the system is installed, the radon levels begin to drop almost immediately. Passive radon reduction techniques (such as sealing cracks or installing pipes without an inline fan) are rarely effective at reducing radon levels. The reason that these "passive" techniques are ineffective is because radon gas is under pressure and must escape from the ground. It is a very inert, un-reactive gas that can be drawn up through the pours of concrete, around drains, utility penetrations, or expansion joints. Attempting to "seal out" radon is similar to trying to keep water out of a basement by painting the walls and floor with waterproofing paint. It may work temporarily if the problem is minor, but it wouldn't keep standing water out. The only way to fix a water problem is to redirect the water somewhere else before it enters the home. The same principles apply to radon correction. Sealing cracks and openings is part of the radon mitigation process; however this is to prevent the downward draw of conditioned air from the home and to improve the pressure field extension of the system below the slab.
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Radon gas mitigation, reduction - testing: Denver, Boulder, Colorado Springs, Milford, New Haven, Stamford, Connecticut CT, Wilmington Delaware, Indianapolis, South Bend, Fort Wayne, Bloomington, Indiana, Lexington, Louisville, Kentucky KY, Baltimore Maryland MD, Boston, Worcester, Massachusetts, Lansing, Ann Arbor, Kalamazoo, Grand Rapids, Brighton Michigan, New York, Pittsburgh, Philadelphia, Allentown, Harrisburg, Pennsylvania PA, West Virginia WV, Madison, Milwaukee, Janesville, Wisconsin
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 | Radon Information Center
Radon Mitigation (Reduction of Radon Gas):
Indoor radon can be mitigated by sealing basement foundations, water drainage, or by sub-slab de-pressurization. In severe cases, mitigation can use air pipes and fans to exhaust sub-slab air to the outside. Indoor ventilation systems are more effective, but exterior ventilation can be cost-effective in some cases. Modern construction that conserves energy by making homes air tight exacerbates the risks of radon exposure if radon is present in the home. Older homes with more porous construction are more likely to vent radon naturally. Ventilation systems can be combined with a heat exchanger to recover energy in the process of exchanging air with the outside. Homes built on a crawl space can benefit from a radon collector installed under a radon barrier (a sheet of plastic that covers the crawl space).
The most common approaches are active soil depressurization (ASD) and mechanical ventilation (MV). Experience has shown that neither is applicable to all buildings with radon problems. A less common approach works efficiently by reducing air pressures within cavities of exterior and demising walls where radon emitting from building materials, most often concrete blocks, collects.
- Nearly all mechanical ventilation-based radon control systems are of fixed rate operation, and even if the indoor relative humidity in the interior of a building goes high, they will continue to inject moisture-laden air into this wet environment increasing the likelihood of mold growth. This is especially risky in hot, humid climates. It is not an unusual practice for radon mitigators in hot, humid climates to warn of possible resulting mold problems by way of an easily removed warning sticker.
- Above Slab Air Pressure Differential Barrier technology ASAPDB requires that the interior pressure envelope, most often drywall, as well as all ductwork for air conditioning systems, be made as airtight as possible. A small blower, often no more than 15 cubic feet per minute may then extract the radon-laden air from these cavities and exhaust it to the out of doors. With well-sealed HVAC ducts, very small negative pressures, perhaps as little as 0.5 pascal, will prevent the entry of highly radon-laden wall cavity air from entering into the breathing zone. Such ASAPDB technology is often the best radon mitigation choice for high rise condominiums as it does not increase indoor humidity loads in hot humid climates, and it can also work well to prevent mold growth in exterior walls in heating climates.
- In hot, humid climates, heat recovery ventilators HRV as well as energy recovery ventilators ERV have a record of increasing indoor relative humidity and increased dehumidification demands on air conditioning systems. In some cases, it is not unlikely that serious mold problems have an origin in HRV and ERV operation in hot, humid climates. HRVs and ERVs have an excellent record in heating climates.
- A recently revealed technology is based in building science. It includes a variable rate mechanical ventilation system that prevents indoor relative humidity from rising above a preset level such as 50% which is currently suggested by the USEPA and others as an upper limit for the prevention of mold. It appears to be especially promising for radon mitigation in hot, humid climates.
- It is generally assumed that air conditioner operation will remove excess moisture from the air in the breathing zone. Just because you have cooling does not mean that you have dehumidification.
- Factors that are likely to aggravate indoor humidity problems from mechanical ventilation-based radon installations are as follows and an expert radon mitigator/building scientist will check for and correct any and all of the following when he performs his radon mitigation procedure:
1. Air conditioner duct leaks located outside the breathing zone, such as in the attic. 2. Excessive exhaust fan operation 3. Oversize or over-capacity air conditioners 4. AC air handler fans that do not stop running when the air conditioner compressor stops running. 5. A radon system air intake located close to a clothes dryer exhaust. 6. delta t, which is the number of degrees that the air is cooled as it is passed over the air conditioner's cooling coils. A good delta t performance figure for home air conditioners is about 20 degrees Fahrenheit. In comparison, automobile air conditioners deliver delta t performance of 32-38 degrees F. A delta t of 14 degrees will dehumidify poorly if at all.
In South Florida, most all radon mitigation is performed by use of fixed rate mechanical ventilation. Radon mitigation training in Florida does not include any segment addressing mechanical ventilation or of problems associated with mechanical ventilation systems such as high indoor humidity, mold, moldy odors, property damage or health consequences of human occupation in high humidity of moldy environments. As a result, most Florida radon mitigators are unaware of and do not incorporate existing building science moisture management technology into mechanical ventilation radon installations.
- ^ "ASTM E2121-03 Standard Practice for Installing Radon Mitigation Systems in Existing Low-Rise Residential Buildings". ASTM International. Retrieved on 2008-02-02.
- ^ "Residential Measurement Provider". The National Environmental Health Association -- National Radon Proficiency Program. Retrieved on 2008-02-02.
- ^ "Radon Measurement Method Definitions". The National Environmental Health Association -- National Radon Proficiency Program. Retrieved on 2008-02-02.
- ^ "You've found radon in your home - what should you do?". Air Chek, Inc.. Retrieved on 2008-02-02.
- ^ "National Radon Proficiency Program". The National Environmental Health Association -- National Radon Proficiency Program. Retrieved on 2008-02-02.
- ^ "Residential Mitigation Provider". The National Environmental Health Association -- National Radon Proficiency Program. Retrieved on 2008-02-02.
- ^ "Radon Mitigation Methods". Radon Solution -- Raising Radon Awareness. Retrieved on 2008-12-02.
ABOUT RADON GAS:
Radon is a colorless, odorless, naturally occurring, radioactive noble gas that is formed from the decay of radium. It is one of the heaviest substances that remains a gas under normal conditions and is considered to be a health hazard. The most stable isotope, 222Rn, has a half-life of 3.8 days and is used in radiotherapy. While having been less studied by chemists due to its radioactivity, there are a few known compounds of this generally unreactive element.
Radon is a significant contaminant that affects indoor air quality worldwide. Radon gas from natural sources can accumulate in buildings, especially in confined areas such as the basement. Radon can be found in some spring waters and hot springs.
According to the United States Environmental Protection Agency, radon is reportedly the second most frequent cause of lung cancer, after cigarette smoking; and radon-induced lung cancer the 6th leading cause of cancer death overall. According to the same sources, radon reportedly causes 21,000 lung cancer deaths per year in the United States. |
Radon Mitigation Systems Diagrams & Photos 
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