|
Office of Air and Radiation
Office of Radiation and Indoor Air
Indoor Environments Division (6609J)
EPA 402-R-93-078, October 1993 (Revised April 1994)
Disclaimer
The U.S. Environmental Protection Agency (EPA) strives to provide
accurate, complete, and useful information. However, neither EPA nor any
person contributing to the preparation of this document makes any
warranty, express or implied, with respect to the usefulness or
effectiveness of any information, method, or process disclosed in this
material. Nor does EPA assume any liability for the use of, or for
damages arising from the use of, any information, method, or process
disclosed in this document.
Mention of firms, trade names, or commercial products in this
document does not constitute endorsement or recommendation for use.
Editor's Note: The on-line version of this document has
been modified slightly from the 1994 printed version to contain
hypertext links to online versions of EPA documents. Please note that
EPA shut down
its operation of the National Radon Proficiency Program (RPP) on
September 30, 1998. References to the Radon Contractor Proficiency (RCP)
Program or EPA's National Radon Proficiency Program (RPP) Mitigation
Service Providers, are no longer applicable.
1.0 Background
2.0 Purpose
3.0 Participants
4.0 Scope
5.0 Assumptions
6.0 Implementation
7.0 Limitations
8.0 Reference Documents
9.0 Description of Terms
10.0 General Practices
11.0 Building Investigation
12.0 Worker Health and Safety
13.0 Systems Design
14.0 Systems Installation
15.0 Materials
16.0 Monitors and Labeling
17.0 Post-Mitigation Testing
18.0 Contracts and Documentation
Appendix A - Mitigation Project Record (the form is
not available here) [find out how to order this appendix and this
document]
The 1988 Indoor Radon Abatement Act (IRAA) required the
Environmental Protection Agency (EPA) to develop a voluntary program
to evaluate and provide information on contractors who offer radon
control services to homeowners. The Radon Contractor Proficiency (RCP)
Program was established to fulfill this portion of the IRAA. In
December 1991, EPA published "Interim Radon Mitigation Standards" as
initial guidelines for evaluating the performance of radon mitigation
contractors under the RCP Program. Over the past six years, the
effectiveness of the basic radon mitigation techniques set forth in
the "Interim Standards" has been validated in field applications
throughout the United States. This experience now serves as the basis
for the more detailed and final Radon Mitigation Standards (RMS) set
forth in this document.
Please note that EPA shut down its
operation of the National Radon Proficiency Program (RPP) on
September 30, 1998. References to the Radon Contractor Proficiency (RCP)
Program or EPA's National Radon Proficiency Program (RPP) Mitigation
Service Providers, are no longer applicable.
The purpose of the RMS is to provide radon mitigation contractors
with uniform standards that will ensure quality and effectiveness in
the design, installation, and evaluation of radon mitigation systems
in detached and attached residential buildings three stories or less
in height. The RMS is intended to serve as a model set of requirements
which can be adopted or modified by state and local jurisdictions to
fulfill objectives of their specific radon contractor certification or
licensure programs.
Minimum requirements are established in the RMS for individuals
nationwide who perform radon remediation work and wish to participate
in EPA's RPP as Mitigation Service Providers. To successfully
participate in EPA's RPP, the mitigation contractor shall have
completed all training, examination and other program requirements and
shall agree to follow the provisions of the RMS.
The requirements addressed in the RMS include the following
categories of contractor activity: General Practices, Building
Investigation, Worker Health and Safety, Systems Design, Systems
Installation, Materials, Monitors and Labeling, Post-Mitigation
Testing, and Contracts and Documentation.
Before applying the provisions of the RMS, it is assumed that
appropriate radon/radon decay product measurements have been performed
within the structure, and that the owner has decided that radon
remediation is necessary.
| 6.1 |
The RMS includes
requirements for installation of radon remediation systems and
provides a basis for evaluating the quality of those installations.
It may be adopted by state regulatory agencies for state or local
radon mitigation contractor licensure programs. It may also be used
as a reference during inspection of in-progress or completed radon
mitigation work. |
| 6.2 |
Contractors shall
personally conduct follow-up inspection of any radon mitigation
systems installed by their firm or by subcontractors to insure
conformance with the requirements of the RMS. This requirement shall
include the post-mitigation testing prescribed in paragraph 17.0. |
| 6.3 |
EPA will evaluate reports
of non-compliance with the RMS that are referred to the Agency by
states and other agencies that monitor radon mitigation services.
Based on its evaluation, EPA may initiate established RCP program
de-listing procedures against contractors that the Agency or States
(with certification programs) find are in violation of the mandatory
provisions of the RMS (See paragraph 6.4). In addition, EPA or its
agent may conduct inspections of radon mitigation projects. State
radon program personnel or their contracted representatives are
considered EPA agents for conducting such inspections. |
| 6.4 |
Those provisions of the
RMS that are considered to be mandatory are prefaced by the term
"shall." Provisions that are considered good practice but which are
not mandatory are prefaced by the terms "should" or "recommended." |
| 6.5 |
The RMS will be updated as
necessary, and in response to technological advances and field
experience.
 |
| 7.1 |
Although the provisions of
the RMS have been carefully reviewed for potential conflicts with
other regulatory requirements, adherence to the RMS does not
guarantee compliance with the applicable codes or regulations of any
other Federal, state, or local agency having jurisdiction. |
| 7.2 |
Where discrepancies exist
between provisions of the RMS and local codes or regulations, local
codes shall take precedence. However, where compliance with local
codes necessitates a deviation from the RMS, EPA recommends that RPP
listed Mitigation Service Providers (mitigation contractors) report
the deviation in writing to the appropriate EPA Regional Office and
the appropriate state regulatory official within 30 days. It should
be noted that EPA is not requiring the reporting that is recommended
in this paragraph. States with radon mitigation contractor
certification programs may require that contractors give prior
notification of their intent to deviate from the RMS for research or
other purposes. |
| 7.3 |
The RMS is not intended to
be used as a design manual, and compliance with its provisions will
not guarantee reduction of indoor radon concentrations to any
specific level. |
| 7.4 |
The RMS shall not apply to
radon mitigation systems installed prior to its effective date,
except when a previously installed system is altered. "Altering"
radon mitigation systems does not include activities such as
replacing worn out equipment, or providing new filters, while
leaving the remainder of the system unchanged. Mitigation systems
installed prior to the effective date of the RMS should be in
compliance with the requirements in force at that time (i.e. EPA
Interim Radon Mitigation Standards, December 15, 1991, as amended by
the Addendum on Backdrafting of October 1, 1992). If a radon
mitigation system is found that does not comply with current
standards, contractors should recommend to clients that the system
be upgraded or altered to meet current standards. |
| 7.5 |
Because of the wide
variation in building design, size, operation and use, the RMS does
not include detailed guidance on how to select the most appropriate
mitigation strategy for a given building. That guidance is provided
in the documents referenced in paragraphs 8.1, 8.2, and 8.3. |
| 7.6 |
The provisions of the RMS
are limited to proven technologies and methods. Publication of this
standard is not intended, however, to inhibit research and
evaluation of other innovative radon mitigation techniques. When
such research is conducted, a performance standard shall be applied,
i.e., post-mitigation radon levels shall be at or below EPA's action
level (currently 4 pCi/L), and the systems design criteria in
paragraph 13.0 shall be applied. Contractors who expect to deviate
from proven radon mitigation technologies and methods (as defined in
the RMS and other EPA references in Section 8.0) for purposes of
research on innovative mitigation techniques, shall obtain prior
approval from state regulatory offices, document the non-standard
techniques, and inform the client of the deviation from standard
procedures. In cases where radon mitigation is not regulated by the
state, contractors shall obtain prior approval from a Regional EPA
office. |
| 7.7 |
At this time, the RMS does
not include standards for installing systems to mitigate radon in
water. However, EPA is currently developing a standard that will
regulate radon levels in domestic water supplies. Following
publication of that standard, the RMS may be revised, as
appropriate, to include standards for installation of systems that
are effective in reducing radon levels in water. |
The following documents are sources of additional radon mitigation
information.
| 8.1 |
EPA Training Manual,
"Reducing Radon In Structures," (Third Edition), January 1993. |
| 8.2 |
"Radon Reduction
Techniques for Detached Houses, Technical Guidance (Second Edition)"
EPA/625/5-87/019, January 1988. |
| 8.3 |
"Application of Radon
Reduction Methods," EPA/625/5-88/024, August 1988. |
| 8.4 |
"Indoor
Radon and Radon Decay Product Measurement Device Protocols," EPA
402-R-92-004, July, 1992. |
| 8.5 |
"Protocols
for Radon and Radon Decay Product Measurements in Homes," EPA
402-R-92-003, June, 1993. |
| 8.6 |
"A
Citizen's Guide To Radon (Second Edition)" EPA 402-K92-001, May
1992. |
| 8.7 |
"Consumer's
Guide to Radon Reduction," EPA, 402-K92-003, August, 1992. |
| 8.8 |
"Home
Buyer's and Seller's Guide to Radon," EPA 402-R-93-003, March,
1993. |
| 8.9 |
"ASHRAE Standard 62-1989,"
Appendix B, Positive Combustion Air Supply. |
| 8.10 |
"National Gas Code,"
Appendix H (p.2223.1-98), 1988, Recommended Procedure for Safety
Inspection of an Existing Appliance Installation. |
| 8.11 |
"Chimney Safety Tests
User's Manual," Second Edition, January 12, 1988, Scanada Shelter
Consortium Inc., for Canada Mortgage and Housing Corp. |
| 8.12 |
OSHA "Safety and Health
Regulations for Construction, Ionizing Radiation," 29 CFR 1926.53. |
| 8.13 |
OSHA "Occupational Safety
and Health Regulations, Ionizing Radiation," 29 CFR 1910.96. |
| 8.14 |
NIOSH "Guide to Industrial
Respiratory Protection," DHHS (NIOSH) Publication No. 87-116,
September, 1987. |
| 8.15 |
NCRP "Measurement of Radon
and Radon Decay Daughters in Air," NCRP Report No. 97, Nov 1988. |
| 8.16 |
EPA "Handbook, Sub-Slab
Depressurization for Low Permeability Fill Material,"
EPA/625/6-91/029, July 1991. |
| 8.17 |
"Radon Reduction
Techniques for Existing Detached Houses, Technical Guidance (Third
Edition) for Active Soil Depressurization Systems,"
EPA/625/R-93-011, October, 1993. |
For this document, certain terms are defined in this section. Terms
not defined herein should have their ordinary meaning within the context
of their use. Ordinary meaning is as defined in "Webster's Ninth New
Collegiate Dictionary."
| 9.1 |
Backdrafting: A
condition where the normal movement of combustion products up a
flue, resulting from the buoyant forces on the hot gases, is
reversed, so that the combustion products can enter the house.
Backdrafting of combustion appliances (such as fireplaces and
furnaces) can occur when depressurization in the house overwhelms
the buoyant force on the hot gases. Backdrafting can also be caused
by high air pressures or blockage at the chimney or flue
termination. |
| 9.2 |
Backer Rod: A
semi-rigid foam material resembling a rope of various diameters.
Used to fill around pipes, etc. to assist in making a sealed
penetration. For example, where a pipe is inserted through a
concrete slab, a length of backer rod is jammed into the opening
around the pipe. Caulking is then applied to the space above the
backer rod and between the outside of the pipe and the slab opening.
The purpose of the backer rod is to hold the semi-fluid caulk in
place until it sets or hardens. |
| 9.3 |
Block Wall
Depressurization: A radon mitigation technique that
depressurizes the void network within a block wall foundation by
drawing air from inside the wall and venting it to the outside. |
| 9.4 |
Perimeter Channel
Drain: A means for collecting water in a basement by means of a
large gap or channel between the concrete floor and the wall.
Collected water may flow to aggregate beneath the slot ("French
Drain") or to a sump where it can be drained or pumped away. |
| 9.5 |
Certified: A rating
applied by some jurisdictions to individuals or firms that are
qualified and authorized to provide radon testing or mitigation
services within the area of their jurisdiction. |
| 9.6 |
Client: The person,
persons, or company that contracts with a radon mitigation
contractor to install a radon reduction system in a building. |
| 9.7 |
Combination
Foundations: Buildings constructed with more than one foundation
type, e.g., basement/crawlspace or basement/slab-on-grade. |
| 9.8 |
Communication Test:
A diagnostic test designed to qualitatively measure the ability of a
suction field and air flow to extend through the material beneath a
concrete slab floor and thus evaluate the potential effectiveness of
a sub-slab depressurization system. This qualitative test is
commonly conducted by applying suction on a centrally located hole
drilled through the concrete slab and simultaneously observing the
movement of smoke downward into small holes drilled in the slab at
locations separated from the central suction hole. (See also
paragraph 9.16, Pressure Field Extension.) |
| 9.9 |
Contractor: An
individual listed in EPA's RPP program, specifically one listed as a
"Mitigation Service Provider," or certified by a state which
requires adherence to the RMS. |
| 9.10 |
Crawlspace
Depressurization: A radon control technique designed to achieve
lower air pressure in the crawlspace relative to indoor air pressure
by use of a fan-powered vent drawing air from within the crawlspace.
(See also paragraph 9.14, Mechanically Ventilated Crawlspace
System.) |
| 9.11 |
Diagnostic Tests:
Procedures used to identify or characterize conditions within
buildings that may contribute to radon entry or elevated radon
levels or may provide information regarding the performance of a
mitigation system. |
| 9.12 |
Drain Tile Loop: A
continuous length of drain tile or perforated pipe extending around
all or part of the internal or external perimeter of a basement or
crawlspace footing. |
| 9.13 |
Mitigation System:
Any system or steps designed to reduce radon concentrations in the
indoor air of a building. |
| 9.14 |
Mechanically Ventilated
Crawlspace System: A radon control technique designed to
increase ventilation within a crawlspace, achieve higher air
pressure in the crawlspace relative to air pressure in the soil
beneath the crawlspace, or achieve lower air pressure in the
crawlspace relative to air pressure in the living spaces, by use of
a fan. (See also paragraph 9.10, Crawlspace Depressurization.) |
| 9.15 |
pCi/L: The
abbreviation for picocuries per liter which is a unit of measure for
the amount of radioactivity in a liter of air. The prefix "pico"
means a multiplication factor of 1 trillionth. A Curie is a commonly
used measurement of radioactivity. |
| 9.16 |
Pressure Field
Extension: The distance that a pressure change is induced in the
sub-slab area, measured from a single or multiple suction points.
(See also paragraph 9.8, Communication Test.) |
| 9.17 |
Radon: A naturally
occurring radioactive element (Rn-222) which exists as a gas and is
measured in picocuries per liter (pCi/L). |
| 9.18 |
Radon Decay Products:
The four short-lived radioactive elements (Po-218, Pb-214,
Bi-214, Po-214) which exist as solids and immediately follow Rn-222
in the decay chain. They are measured in working levels (WL). |
| 9.19 |
Re-Entrainment: The
unintended re-entry into a building of radon that is being exhausted
from the vent of a radon mitigation system. |
| 9.20 |
Soil Gas: The gas
mixture present in soil which may contain radon. |
| 9.21 |
Soil-Gas Retarder:
A continuous membrane or other comparable material used to retard
the flow of soil gases into a building. |
| 9.22 |
Stack Effect: The
overall upward movement of air inside a building that results from
heated air rising and escaping through openings in the building
envelope, thus causing indoor air pressure in the lower portions of
a building to be lower than the pressure in the soil beneath or
surrounding the building foundation. |
| 9.23 |
Sub-Membrane
Depressurization: A radon control technique designed to achieve
lower air pressure in the space under a soilgas retarder membrane
laid on the crawl- space floor, relative to air pressure in the
crawlspace, by use of a fan-powered vent drawing air from beneath
the membrane. |
| 9.24 |
Sub-Slab
Depressurization (Active): A radon control technique designed to
achieve lower sub-slab air pressure relative to indoor air pressure
by use of a fan-powered vent drawing air from beneath the concrete
slab. |
| 9.25 |
Sub-Slab
Depressurization (Passive): A radon control technique designed
to achieve lower sub-slab air pressure relative to indoor air
pressure by use of a vent pipe (without a fan) routed through the
conditioned space of a building and connecting the sub-slab area to
the outdoor air. This system relies primarily on the convective flow
of warmed air upward in the vent to draw air from beneath the
concrete slab. |
| 9.26 |
Working Level (WL):
A unit of radon decay product exposure rate. Numerically, any
combination of short-lived radon decay products in one liter of air
that will result in the ultimate emission of 130,000 MeV of
potential alpha energy. This number was chosen because it is
approximately the total alpha energy released from the short-lived
decay products in equilibrium with 100 pCi of Rn-222 per liter of
air. (See also the referenced document in paragraph 8.15.) |
| 9.27 |
Working Level Month (WLM):
A unit of exposure used to express the accumulated human
exposure to radon decay products. It is calculated by multiplying
the average working level to which a person has been exposed by the
number of hours exposed and dividing the product by 170. |
The following general practices are required for all contacts between
radon mitigation contractors and clients.
| 10.1 |
In the initial contact
with a client, the contractor shall review any available results
from previous radon tests to assist in developing an appropriate
mitigation strategy. |
| 10.2 |
Based on guidance
contained in "A
Citizen's Guide to Radon (Second Edition)," (paragraph 8.6) or
subsequent revisions of that document, the contractor shall refer
the client to the discussions of interpreting indoor radon test
results and the health risk associated with the radon level found in
the building. The "Consumer's
Guide to Radon Reduction," (paragraph 8.7) is an appropriate
reference for providing advice on actions to take to reduce indoor
radon levels. Similar documents developed by states and mandated for
dissemination by state regulations may also be used as references. |
| 10.3 |
When delays in the
installation of a permanent radon control system are unavoidable due
to building conditions or construction activities, and a temporary
system is installed, the contractor shall inform the client about
the temporary nature of the system. A label that is readable from at
least three feet shall be placed on the system. The label shall
include a statement that the system is temporary and that it will be
replaced with a permanent system within 30 days. The label shall
also include the date of installation, and the contractor's name,
phone number, and RPP Identification Number. (EXCEPTION: The 30 day
limit on use of a temporary mitigation system may be extended in
cases where a major renovation or change in building use
necessitates a delay in installation of a permanent mitigation
system that is optimized to the new building configuration or use.
The appropriate state or local building official or radon program
official should be notified when this exception is being applied.) |
| 10.4 |
When the selected
mitigation technique requires use of sealants, caulks, or bonding
chemicals containing volatile solvents, prior to starting work the
contractor shall inform the client of the need to ventilate work
areas during and after the use of such materials. Ventilation shall
be provided as recommended by the manufacturer of the material. |
| 11.1 |
The contractor shall
conduct a thorough visual inspection of the building prior to
initiating any radon mitigation work. The inspection is intended to
identify any specific building characteristics and configurations
(e.g., large cracks in slabs, exposed earth in crawlspaces, open
stairways to basements) and operational conditions (e.g.,
continuously running HVAC systems or operational windows) that may
affect the design, installation, and effectiveness of radon
mitigation systems. As part of this inspection, clients should be
asked to provide any available information on the building (e.g.,
construction specifications, pictures, drawings, etc.) that might be
of value in determining the radon mitigation strategy. |
| 11.2 |
To facilitate selection of
the most effective radon control system and avoid the costs of
installing systems that subsequently prove to be ineffective, it is
recommended that the contractor conduct diagnostic tests to assist
in identifying and verifying suspected radon sources and entry
points. Radon grab sampling, continuous radon monitoring, and use of
chemical smoke sticks are examples of the type of diagnostic testing
commonly used. (See paragraph 11.4). |
| 11.3 |
It is recommended that
during the building investigation, contractors routinely perform
diagnostic tests to evaluate the existence of, or the potential for,
backdrafting of natural draft combustion appliances. Published
procedures for conducting backdrafting tests are covered in the
Reference Documents listed in Paragraphs 8.9, 8.10, and 8.11. The
following checklist has been extracted from material in these
references and may be used to test for existing or potential
backdrafting conditions:
- Close all windows and doors, both external and internal.
- Open all HVAC supply and return air duct vents/registers.
- Close fireplace and wood stove dampers.
- Turn on all exhaust and air distribution fans and combustion
appliances EXCEPT the appliance being tested for backdrafting.
- Wait 5 minutes.
- Test to determine the indoor-outdoor pressure differential in
the room where the appliance being tested is located. If the
pressure differential is a negative 5 Pascals or more, assume that
a potential for backdrafting exists.
- To begin a test for actual spillage of flue gases, turn on the
appliance being tested. (If the appliance is a forced air furnace,
ensure that the blower starts to run before proceeding.)
- Wait 5 minutes.
- Using either a smoke tube or a carbon dioxide gas analyzer,
check for flue gas spillage near the vent hood.
- Repeat steps (4) through (9) for each natural draft combustion
appliance being tested for backdrafting. Seasonal and extreme
weather conditions should be considered when evaluating pressure
differentials and the potential for backdrafting.
If spillage is confirmed from any natural draft combustion
appliance, clients shall be advised of the backdrafting condition
and that active (fan-powered) radon mitigation systems cannot be
installed until the condition has been corrected. Contractors should
advise the client to contact an HVAC contractor if correcting an
existing or potential backdrafting condition is necessary. (See
paragraph 17.3 for post-mitigation backdrafting testing.) |
| 11.4 |
If installation of a
sub-slab depressurization system is contemplated and characteristics
of the sub-slab material are unknown, a communication test, as
defined in paragraph 9.8 is recommended. |
| 11.5 |
As part of the building
investigation, a floor-plan sketch shall be developed (if not
already in existence and readily available) that includes
illustrations of the building foundation (slab-on-grade, basement or
crawlspace area.) The sketch should include the location of
load-bearing walls, drain fixtures and HVAC systems. It should be
annotated to include suspected or confirmed radon entry points,
results of any diagnostic testing, the anticipated layout of any
radon mitigation system piping, and the anticipated locations of any
vent fan and system warning devices for the envisioned mitigation
systems. The sketch shall be finalized during installation and shall
be included in the documentation. (See paragraph 18.2 and Appendix
A.) |
| 12.1 |
Contractors shall comply
with all OSHA, state and local standards or regulations relating to
worker safety and occupational radon exposure. Applicable references
in the Code of Federal Regulations and NIOSH publications are listed
in paragraphs 8.12, 8.13, and 8.14. |
| 12.2 |
In addition to the OSHA
and NIOSH standards, the following requirements that are
specifically or uniquely applicable for the safety and protection of
radon mitigation workers shall be met:
| 12.2.1 |
The contractor shall
advise workers of the hazards of exposure to radon and the need
to apply protective measures when working in areas of elevated
radon concentrations. |
| 12.2.2 |
The contractor shall
have a worker protection plan on file that is available to all
employees and is approved by any state or local regulating
agencies that require such a plan. Exception: A worker
protection plan is not required for a contractor who is a sole
proprietor unless required by state or local regulations. |
| 12.2.3 |
The contractor shall
ensure that appropriate safety equipment such as hard hats, face
shields, ear plugs, steel-toe boots and protective gloves are
available on the job site during cutting, drilling, grinding,
polishing, demolishing or other activity associated with radon
mitigation projects. |
| 12.2.4 |
All electrical
equipment used during radon mitigation projects shall be
properly grounded. Circuits used as a power source should be
protected by Ground-fault Circuit Interrupters (GFCI). |
| 12.2.5 |
When work is required
at elevations above the ground or floor, the contractor shall
ensure that ladders or scaffolding are safely installed and
operated. |
| 12.2.6 |
Work areas shall be
ventilated to reduce worker exposure to radon decay products,
dust, or other airborne pollutants. In work areas where
ventilation is impractical or where ventilation cannot reduce
radon levels to less than 0.3 WL (based on a short term
diagnostic test, e.g., grab sample), the contractor shall ensure
that respiratory protection conforms with the requirements in
the NIOSH Guide to Industrial Respiratory Protection. (See
paragraph 8.14.) (Note: If unable to make working level
measurements, a radon level of 30 pCi/L shall be used.) |
| 12.2.7 |
Where combustible
materials exist in the specific area of the building where radon
mitigation work is to be conducted and the contractor is
creating any temperatures high enough to induce a flame, the
contractor shall ensure that fire extinguishers suitable for
type A, B, and C fires are available in the immediate work area. |
| 12.2.8 |
Pending development of
an approved personal radon exposure device and a protocol for
its use, contractors shall record employee exposure to radon at
each work site, based on:
- the highest pre-mitigation indoor radon or working level
measurement available, and
- the time employees are exposed (without respirator
protection) at that level (See paragraph 12.2.6.)
(Note: This approach is not intended to preclude the
alternative use of on-site radon or radon decay product
measurements to determine exact exposure.) Consistent with OSHA
Permissible Exposure Limits, contractors shall ensure that
employees are exposed to no more than 4 working level months (WLM)
over a 12 month period. (An equilibrium ratio of 50 percent
shall be used to convert radon exposure to WLM.) |
| 12.2.9 |
In any planned work
area where it is suspected that friable asbestos may exist and
be disturbed, radon mitigation work shall not be conducted until
a determination is made by a properly trained or accredited
person that such work will be undertaken in a manner which
complies with applicable asbestos regulations. |
| 12.2.10 |
When mitigation work
requires the use of sealants, adhesives, paints, or other
substances that may be hazardous to health, contractors shall
provide employees with the applicable Material Safety Data
Sheets (MSDS) and explain the required safety procedures. |
|
| 13.1 |
All radon mitigation
systems shall be designed and installed as permanent, integral
additions to the building, except where a temporary system has been
installed in accordance with paragraph 10.3. |
| 13.2 |
All radon mitigation
systems shall be designed to avoid the creation of other health,
safety, or environmental hazards to building occupants, such as
backdrafting of natural draft combustion appliances. |
| 13.3 |
All radon mitigation
systems shall be designed to maximize radon reduction and in
consideration of the need to minimize excess energy usage, to avoid
compromising moisture and temperature controls and other comfort
features, and to minimize noise. |
| 13.4 |
All radon mitigation
systems and their components shall be designed to comply with the
laws, ordinances, codes, and regulations of relevant jurisdictional
authorities, including applicable mechanical, electrical, building,
plumbing, energy, and fire prevention codes.
Back Home |
14.1 General Requirements
| |
14.1.1 |
All components of radon
mitigation systems installed in compliance with provisions of the
RMS shall also be in compliance with the applicable mechanical,
electrical, building, plumbing, energy and fire prevention codes,
standards, and regulations of the local jurisdiction. |
| |
14.1.2 |
The contractor shall
obtain all required licenses and permits, and display them in the
work areas as required by local ordinances. |
| |
14.1.3 |
Where portions of
structural framing material must be removed to accommodate radon
vent pipes, material removed shall be no greater than that permitted
for plumbing installations by applicable building or plumbing codes. |
| |
14.1.4 |
Where installation of a
radon mitigation system requires pipes or ducts to penetrate a
firewall or other fire resistance rated wall or floor, penetrations
shall be protected in accordance with applicable building,
mechanical, fire, and electrical codes. |
| |
14.1.5 |
When installing radon
mitigation systems that use sump pits as the suction point for
active soil depressurization, if sump pumps are needed, it is
recommended that submersible sump pumps be used. (See paragraphs
14.5.1, 14.7.4, 15.7, and 15.8.) |
14.2 Radon Vent Pipe Installation Requirements
| |
14.2.1 |
All joints and connections
in radon mitigation systems using plastic vent pipes shall be
permanently sealed with adhesives as specified by the manufacturer
of the pipe material used. (See paragraph 14.3.7 for exception when
installing fans, and paragraph 14.2.7 for exception when installing
vent pipes in sumps.) Joints or connections in other vent pipe
materials shall be made air tight. |
| |
14.2.2 |
Attic and external piping
runs in areas subject to subfreezing conditions should be protected
to avoid the risk of vent pipe freeze-up. |
| |
14.2.3 |
Radon vent pipes shall be
fastened to the structure of the building with hangers, strapping,
or other supports that will adequately secure the vent material.
Existing plumbing pipes, ducts, or mechanical equipment shall not be
used to support or secure a radon vent pipe. |
| |
14.2.4 |
Supports for radon vent
pipes shall be installed at least every 6 feet on horizontal runs.
Vertical runs shall be secured either above or below the points of
penetration through floors, ceilings, and roofs, or at least every 8
feet on runs that do not penetrate floors, ceilings, or roofs. |
| |
14.2.5 |
To prevent blockage of air
flow into the bottom of radon vent pipes, these pipes shall be
supported or secured in a permanent manner that prevents their
downward movement to the bottom of suction pits or sump pits, or
into the soil beneath an aggregate layer under a slab. |
| |
14.2.6 |
Radon vent pipes shall be
installed in a configuration that ensures that any rain water or
condensation within the pipes drains downward into the ground
beneath the slab or soil-gas retarder membrane. |
| |
14.2.7 |
Radon vent pipes shall not
block access to any areas requiring maintenance or inspection. Radon
vents shall not be installed in front of or interfere with any
light, opening, door, window or equipment access area required by
code. If radon vent pipes are installed in sump pits, the system
shall be designed with removable or flexible couplings to facilitate
removal of the sump pit cover for sump pump maintenance. |
| |
14.2.8 |
To prevent re-entrainment
of radon, the point of discharge from vents of fan-powered soil
depressurization and block wall depressurization systems shall meet
all of the following requirements: (1) be above the eave of the
roof, (2) be ten feet or more above ground level, (3) be ten feet or
more from any window, door, or other opening into conditioned spaces
of the structure that is less than two feet below the exhaust point,
and (4) be ten feet or more from any opening into an adjacent
building. The total required distance (ten feet) from the point of
discharge to openings in the structure may be measured either
directly between the two points or be the sum of measurements made
around intervening obstacles. Whenever possible, the exhaust point
should be positioned above the highest eave of the building and as
close to the roof ridge line as possible. |
| |
14.2.9 |
When a radon mitigation
system is designed to draw soil gas from a perimeter drain tile loop
(internal or external) that discharges water through a drain line to
daylight or a soakaway, a one-way flow valve, water trap, or other
control device should be installed in or on the discharge line to
prevent outside air from entering the system while allowing water to
flow out of the system. |
14.3 Radon Vent Fan Installation Requirements
| |
14.3.1 |
Vent fans used in radon
mitigation systems shall be designed or otherwise sealed to reduce
the potential for leakage of soil gas from the fan housing. |
| |
14.3.2 |
Radon vent fans shall be
sized to provide the pressure difference and air flow
characteristics necessary to achieve the radon reduction goals
established for the specific mitigation project. Guidelines for
sizing vent fans and piping can be found in the references cited in
paragraphs 8.1, 8.16, and 8.17. |
| |
14.3.3 |
Radon vent fans used in
active soil depressurization or block wall depressurization systems
shall not be installed below ground nor in the conditioned
(heated/cooled) space of a building, nor in any basement,
crawlspace, or other interior location directly beneath the
conditioned spaces of a building. Acceptable locations for radon
vent fans include attics not suitable for occupancy (including
attics over living spaces and garages), garages that are not beneath
conditioned spaces, or on the exterior of the building. |
| |
14.3.4 |
Radon vent fans shall be
installed in a configuration that avoids condensation buildup in the
fan housing. Whenever possible, fans should be installed in vertical
runs of the vent pipe. |
| |
14.3.5 |
Radon vent fans mounted on
the exterior of buildings shall be rated for outdoor use or
installed in a water tight protective housing. |
| |
14.3.6 |
Radon vent fans shall be
mounted and secured in a manner that minimizes transfer of vibration
to the structural framing of the building. |
| |
14.3.7 |
To facilitate maintenance
and future replacement, radon vent fans shall be installed in the
vent pipe using removable couplings or flexible connections that can
be tightly secured to both the fan and the vent pipe. |
| |
14.3.8 |
The intakes of fans used
in crawlspace pressurization, or in pressurizing the building
itself, shall be screened or filtered to prevent ingestion of debris
or personal injury. Screens or filters shall be removable to permit
cleaning or replacement and building owners shall be informed of the
need to periodically replace or clean such screens and filters. This
information shall also be included in the documentation. (See
paragraph 18.5) |
14.4 Suction Pit Requirement for Sub-Slab Depressurization (SSD)
Systems
| |
14.4.1 |
To provide optimum
pressure field extension of the subslab communication zone, adequate
material shall be excavated from the area immediately below the slab
penetration point of SSD system vent pipes. |
14.5 Sealing Requirements
| |
14.5.1 |
Sump pits that
permit entry of soil-gas or that would allow conditioned air to be
drawn into a sub-slab depressurization system shall be covered and
sealed. The covers on sumps that previously provided protection or
relief from surface water collection shall be fitted with a water or
mechanically trapped drain. Water traps should be fitted with an
automatic supply of priming water. (See paragraph 15.7 for details
on sump cover and sealing materials.) |
| |
14.5.2 |
Openings
around radon vent pipe penetrations of the slab, the foundation
walls, or the crawlspace soil-gas retarder membrane shall be
cleaned, prepared, and sealed in a permanent, air-tight manner using
compatible caulks or other sealant materials. (See paragraph 15.5.)
Openings around other utility penetrations of the slab, walls, or
soil-gas retarder shall also be sealed. |
|
14.5.3 |
Where a Block
Wall Depressurization (BWD) system is used to mitigate radon,
openings in the tops of such walls and all accessible openings or
cracks in the interior surfaces of the walls shall be closed and
sealed with polyurethane or equivalent caulks, expandable foams, or
other fillers and sealants. (See paragraphs 15.5 and 15.6.) Openings
or cracks that are determined to be inaccessible or beyond the
ability of the contractor to seal shall be disclosed to the client
and included in the documentation. |
|
14.5.4 |
Openings,
perimeter channel drains, or cracks that exist where the slab meets
the foundation wall (floor-wall joint), shall be sealed with
urethane caulk or equivalent material. When the opening or channel
is greater than 1/2 inch in width, a foam backer rod or other
comparable filler material shall be inserted in the channel before
application of the sealant. This sealing technique shall be done in
a manner that retains the channel feature as a water control system.
Other openings or cracks in slabs or at expansion or control joints
should also be sealed. Openings or cracks that are determined to be
inaccessible or beyond the ability of the contractor to seal shall
be disclosed to the client and included in the documentation. |
|
14.5.5 |
When
installing baseboard-type suction systems, all seams and joints in
the baseboard material shall be joined and sealed using materials
recommended by the manufacturer of the baseboard system. Baseboards
shall be secured to walls and floors with adhesives designed and
recommended for such installations. If a baseboard system is
installed on a block wall foundation, the tops of the blockwall
shall be closed and sealed as prescribed in paragraph 14.5.3. |
|
14.5.6 |
Any seams in
soil-gas retarder membranes used in crawlspaces for sub-membrane
depressurization systems shall be overlapped at least 12 inches and
should be sealed. To enhance the effectiveness of sub-membrane
depressurization systems, the membrane should also be sealed around
interior piers and to the inside of exterior walls. |
|
14.5.7 |
In combination
basement/crawlspace foundations, where the crawlspace has been
confirmed as a source of radon entry, access doors and other
openings between the basement and the adjacent crawlspace shall be
closed and sealed. Access doors required by code shall be fitted
with air tight gaskets and a means of positive closure, but shall
not be permanently sealed. In cases where both the basement and the
adjacent crawlspace areas are being mitigated with active SSD and
SMD systems, sealing of the openings between those areas is not
required. |
|
14.5.8 |
When
crawlspace depressurization is used for radon mitigation, openings
and cracks in floors above the crawl-space which would permit
conditioned air to pass out of the living spaces of the building,
shall be identified, closed, and sealed. Sealing of openings around
hydronic heat or steam pipe penetrations shall be done using
non-combustible materials. Openings or cracks that are determined to
be inaccessible or beyond the ability of the contractor to seal
shall be disclosed to the client and included in the documentation. |
14.6 Electrical Requirements
| |
14.6.1 |
Wiring for all active
radon mitigation systems shall conform to provisions of the National
Electric Code and any additional local regulations. |
| |
14.6.2 |
Wiring may not be located
in or chased through the mitigation installation ducting or any
other heating or cooling ductwork. |
| |
14.6.3 |
Any plugged cord used to
supply power to a radon vent fan shall be no more than 6 feet in
length. |
| |
14.6.4 |
No plugged cord may
penetrate a wall or be concealed within a wall. |
| |
14.6.5 |
Radon mitigation fans
installed on the exterior of buildings shall be hard-wired into an
electrical circuit. Plugged fans shall not be used outdoors. |
| |
14.6.6 |
If the rated electricity
requirements of a radon mitigation system fan exceeds 50 percent of
the circuit capacity into which it will be connected, or if the
total connected load on the circuit (including the radon vent fan)
exceeds 80 percent of the circuit's rated capacity, a separate,
dedicated circuit shall be installed to power the fan. |
| |
14.6.7 |
An electrical disconnect
switch or circuit breaker shall be installed in radon mitigation
system fan circuits to permit deactivation of the fan for
maintenance or repair by the building owner or servicing contractor
(Disconnect switches are not required with plugged fans). |
14.7 Drain Installation Requirements
| |
14.7.1 |
If drains discharge
directly into the soil beneath the slab or through solid pipe to a
soakaway, the contractor should install a drain that meets the
requirements in paragraph 14.5.1. |
| |
14.7.2 |
If condensate drains from
air conditioning units terminate beneath the floor slab, the
contractor shall install a trap in the drain that provides a minimum
6-inch standing water seal depth, reroute the drain directly into a
trapped floor drain, or reconnect the drain to a condensate pump. |
| |
14.7.3 |
Perimeter (channel or
French) drains should be sealed with backer rods and urethane or
comparable sealants in a manner that will retain the channel feature
as a water control system. (See paragraph 14.5.4.) |
| |
14.7.4 |
When a sump pit is the
only system in a basement for protection or relief from excess
surface water and a cover is installed on the sump for radon
control, the cover shall be recessed and fitted with a trapped drain
meeting the requirements of paragraph 14.5.1. |
14.8 HVAC Installation Requirements
| |
14.8.1 |
Modifications to an
existing HVAC system, which are proposed to mitigate elevated levels
of radon, should be reviewed and approved by the original designer
of the system (when possible) or by a licensed mechanical
contractor. |
| |
14.8.2 |
Foundation vents,
installed specifically to reduce indoor radon levels by increasing
the natural ventilation of a crawlspace, shall be non-closeable. In
areas subject to subfreezing conditions, the existing location of
water supply and distribution pipes in the crawlspace, and the need
to insulate or apply heat tape to those pipes, should be considered
when selecting locations for installing foundation vents. |
| |
14.8.3 |
Heat Recovery Ventilation
(HRV) systems shall not be installed in rooms that contain friable
asbestos. |
| |
14.8.4 |
In HRV installations,
supply and exhaust ports in the interior shall be located a minimum
of 12 feet apart. The exterior supply and exhaust ports shall be
positioned to avoid blockage by snow or leaves and be a minimum of
10 feet apart. |
| |
14.8.5 |
Contractors installing HRV
systems shall verify that the incoming and outgoing airflow is
balanced to ensure that the system does not create a negative
pressure within the building. Contractors shall inform building
owners that periodic filter replacement and inlet grill cleaning are
necessary to maintain a balanced airflow. This information shall
also be included in the documentation. |
| |
14.8.6 |
Both internal and external
intake and exhaust vents in HRV systems shall be covered with wire
mesh or screening to prevent entry of animals or debris or injury to
occupants. |
| 15.1 |
All mitigation system
electrical components shall be U.L. listed or of equivalent
specifications. |
| 15.2 |
As a minimum, all plastic
vent pipes in mitigation systems shall be made of Schedule 20 PVC,
ABS or equivalent piping material. Schedule 40 piping or its
equivalent should be used in garages and in other internal and
external locations subject to weathering or physical damage. |
| 15.3 |
Vent pipe fittings in a
mitigation system shall be of the same material as the vent pipes.
(See paragraph 14.3.7 for exception when installing vent fans, and
paragraph 14.2.7 for exception when installing radon vent pipes in
sump pit covers. |
| 15.4 |
Cleaning solvents and
adhesives used to join plastic pipes and fittings shall be as
recommended by manufacturers for use with the type of pipe material
used in the mitigation system. |
| 15.5 |
When sealing cracks in
slabs and other small openings around penetrations of the slab and
foundation walls, caulks and sealants designed for such application
shall be used. Urethane sealants are recommended because of their
durability. |
| 15.6 |
When sealing holes for
plumbing rough-in or other large openings in slabs and foundation
walls that are below the ground surface, non-shrink mortar, grouts,
expanding foam, or similar materials designed for such application
shall be used. |
| 15.7 |
Sump pit covers shall be
made of durable plastic or other rigid material and designed to
permit air-tight sealing. To permit easy removal for sump pump
servicing, the cover shall be sealed using silicone or other
non-permanent type caulking materials or an air-tight gasket. |
| 15.8 |
Penetrations of sump
covers to accommodate electrical wiring, water ejection pipes, or
radon vent pipes shall be designed to permit air-tight sealing
around penetrations, using caulk or grommets. Sump covers that
permit observation of conditions in the sump pit are recommended.
|
| 15.9 |
Plastic sheeting installed
in crawlspaces as soil-gas retarders shall be a minimum of 6 mil (3
mil cross-laminated) polyethylene or equivalent flexible material.
Heavier gauge sheeting should be used when crawlspaces are used for
storage, or frequent entry is required for maintenance of utilities.
|
| 15.10 |
Any wood used in attaching
soil-gas retarder membranes to crawlspace walls or piers shall be
pressure treated or naturally resistant to decay and termites. |
| 16.1 |
All active soil
depressurization and block wall depressurization radon mitigation
systems shall include a mechanism to monitor system performance and
warn of system failure. The mechanism shall be simple to read or
interpret and be located where it is easily seen or heard by
building occupants and protected from damage or destruction. |
| 16.2 |
Electrical radon
mitigation system monitors (whether visual or audible) shall be
installed on non-switched circuits and be designed to reset
automatically when power is restored after service or power supply
failure. Battery operated monitoring devices shall not be used
unless they are equipped with a low power warning feature. |
| 16.3 |
Mechanical radon
mitigation system monitors, such as manometer type pressure gauges,
shall be clearly marked to indicate the range or zone of pressure
readings that existed when the system was initially activated. |
| 16.4 |
A system description label
shall be placed on the mitigation system, the electric service
entrance panel, or other prominent location. This label shall be
legible from a distance of at least three feet and include the
following information: "Radon Reduction System," the installer's
name, phone number, and RCP Identification Number, the date of
installation, and an advisory that the building should be tested for
radon at least every two years or as required or recommended by
state or local agencies. In addition, all exposed and visible
interior radon mitigation system vent pipe sections shall be
identified with at least one label on each floor level. The label
shall read, "Radon Reduction System." |
| 16.5 |
The circuit breakers
controlling the circuits on which the radon vent fan and system
failure warning devices operate shall be labeled "Radon System."
|
| 17.1 |
After installation of an
active radon control system (e.g., SSD), the contractor shall
re-examine and verify the integrity of the fan mounting seals and
all joints in the interior vent piping. |
| 17.2 |
After installation of any
active radon mitigation system, the contractor shall measure
suctions or flows in system piping or ducting to assure that the
system is operating as designed. (Note: When SSD systems are
installed and activated, a test of pressure field extension is a
good practice, particularly when there is uncertainty regarding the
permeability of materials under all parts of the slab.) |
| 17.3 |
Immediately after
installation and activation of any active (fan-powered) sub-slab
depressurization or block wall depressurization system in buildings
containing natural draft combustion appliances, the building shall
be tested for backdrafting of those appliances. Any backdrafting
condition that results from installation of the radon mitigation
system shall be corrected before the system is placed in operation.
(Procedures and a checklist for conducting backdrafting tests are
covered in the reference documents listed in paragraphs 8.9, 8.10,
and 8.11, and in paragraph 11.3.) |
| 17.4 |
Upon completion of radon
mitigation work, a test of mitigation system effectiveness shall be
conducted using an EPA RPP Analytical Service Provider listed test
device and in accordance with EPA testing protocols or state
requirements. This test should be conducted no sooner than 24 hours
nor later than 30 days following completion and activation of the
mitigation system(s). This test may be conducted by the contractor,
by the client, or by a third party testing firm. If this test is
conducted by the mitigation contractor, and the test results are
accepted by the client as satisfactory evidence of system
effectiveness, further post-mitigation testing is not required.
However, to avoid the appearance of conflict of interest, the
contractor shall recommend to the client that a mitigation system
effectiveness test be conducted by an independent EPA RPP listed
Measurement Service Provider or state certified testing firm or by
the client. The contractor should request a copy of the report of
any post-mitigation testing conducted by the client or by an
independent testing firm. |
| 17.5 |
To ensure continued
effectiveness of the radon mitigation system(s) installed, the
contractor shall advise the client to retest the building at least
every two years or as required or recommended by state or local
authority. Retesting is also recommended if the building undergoes
significant alteration. |
| 18.1 |
EPA recommends that
contractors provide the following written information to clients
prior to initiation of work:
- The contractor's EPA RPP Mitigation Service Provider
identification number.
- A statement that describes the planned scope of the work and
that includes an estimate of the time needed to complete the work.
- A statement describing any known hazards associated with
chemicals used in or as part of the installation.
- A statement indicating compliance with and implementation of
all EPA standards and those of other agencies having jurisdiction
(e.g., code requirements).
- A statement describing any system maintenance that the
building owner would be required to perform.
- An estimate of the installation cost and annual operating
costs of the system.
- The conditions of any warranty or guarantee.
|
| 18.2 |
EPA recommends that RPP
listed mitigation contractors keep records of all radon mitigation
work performed and maintain those records for 3 years or for the
period of any warranty or guarantee, whichever is longer. These
records should include:
- The Building Investigation Summary and floor plan sketch. (See
Appendix A.)
- Pre- and post-mitigation radon test data.
- Pre- and post-mitigation diagnostic test data.
- Copies of contracts and warranties.
- A narrative or pictorial description of mitigation system(s)
installed.
Appendix A contains a suggested standard format for compiling
mitigation project records. |
| 18.3 |
Other records or
bookkeeping required by local, state, or Federal statutes and
regulations shall be maintained for the period(s) prescribed by
those requirements. |
| 18.4 |
EPA recommends that health
and safety records, including worker radon exposure logs, be
maintained for a minimum of 20 years. |
| 18.5 |
Upon completion of the
mitigation project, contractors shall provide clients with an
information package that includes:
- Any building permits required by local codes.
- Copies of the Building Investigation Summary and floor plan
sketch. (See Appendix A.)
- Pre-and post-mitigation radon test data.
- Copies of contracts and warranties.
- A description of the mitigation system installed and its basic
operating principles.
- A description of any deviations from the RMS or State
requirements.
- A description of the proper operating procedures of any
mechanical or electrical systems installed, including
manufacturer's operation and maintenance instructions and
warranties.
- A list of appropriate actions for clients to take if the
system failure warning device indicates system degradation or
failure.
- The name, telephone number, and EPA RPP Mitigation Service
Provider Identification Number of the contractor, and the phone
number of the state radon office.
|
|
