SCHOOL MITIGATION DESIGN CONSIDERATIONS
Bill Brodhead
WPB Enterprises, Inc., 2844 Slifer Valley Rd., Riegelsville, PA USA
wmbrodhead@hotmail.com

ABSTRACT
The state of New Jersey recently required all schools in the state to test for radon. This spring
the NJ DEP contracted with WPB to produce a one day class to instruct New Jersey certified
mitigators how to mitigate schools. Radon mitigators predominately installed ASD systems in
residential buildings. Although commercial radon mitigation systems have most of the same
features as a residential system, there are some significant differences in the system design and
installation. The most important difference is the heating venting and air conditioning system
(HVAC). The HVAC system in schools and commercial buildings can cause the radon
problem, fix the radon problem and interfere with an ASD system performance. In addition the
construction characteristics of school buildings and their large size require more careful design
than residential systems. This paper will review some of the differences between these two types
of installations.

TEAM APPROACH AND MEETING
Schools are obviously more complicated buildings than residences. The variation in construction
characteristics and operation between different schools is also great. A radon mitigator therefore
needs to gather information and expertise from a number of individuals in order to design a
radon mitigation system for a school. The team should consist of school officials, some one
knowledgeable with the HVAC system, someone who can read construction drawings and
possibly an engineer or architect. At the meetings there will need to be, all the radon
measurements, construction blueprints and copies of fire escape plans to make notes on.

REVIEW OF RADON MEASUREMENTS
Radon measurements are often just long lists of classrooms and numbers. These measurements
need to be transcribed on to a fire plan or other simple floor plan. The date the measurements
were made as well as the day of the week should be included on the floor plan. The
measurement pattern along with the HVAC zones that are visible on a floor plan can help define
where the problem is and what might be the cause. This information may also indicate if
additional testing is required to clarify the problem.

UNDERSTANDING THE HVAC SYSTEM
Schools can have multiple W A C systems that effect classrooms differently. The ventilation
portion of the system needs to be thoroughly understood. This includes all exhaust openings and
fans in the building as well as outdoor air sources. It is important to identify HVAC zones
within the building and each zones HVAC type. There are three generic types of HVAC systems
typically used in schools.
Constant Volume System
This system provides a constant airflow. Comfort is maintained by varying the
airflow temperature and humidity
Variable Air Volume (VAV)
Air temperature and humidity are constant while the airflow to each room is
varied by individual VAV boxes
Individual Unit Ventilator
Each room has its own air handler with hot water or steam and sometimes chilled
water provided from a central source.
Each of these different HVAC systems can cause individual rooms to have elevated radon levels
because of the pressure relationships they create with radon sources, the amount of outdoor air
they introduce into the space or the possibility of transferring radon from one area to another. A
continuous radon monitor (CRM) can be used to define the HVAC influence on radon levels.
Micro-manometer measurements of the pressure difference between the main hallway of the
building and the outside and then between individual classrooms and offices and hallway are also
important to understand what pressures are being induced by stack effect and HVAC operation.
Note the HVAC status when the measurements are made. Another important piece of
information is understanding what cycles the HVAC systems are on and how they are controlled
or changed. Pressures inside the building will change as the HVAC operation changes and
exhaust fans are operated.
The mechanical drawings of the building need to be studied with someone, who can interpret
them and locate HVAC components, especially exhaust fans. A list of all the exhaust fans
should be made and then each one visited to determine if they are functional and when they are
being used. Rooms that typically have independent exhaust include kitchens, bathrooms,
chemistry labs, gyms, workshops, nurse's rooms and print rooms.
The outdoor air (OA) supplies to the building also need to be thoroughly understood. This
includes the outdoor air to mechanical rooms as well as the HVAC systems. In many cases it is
necessary to actually inspect outdoor damper positions to confirm they are allowing adequate
amounts of outdoor air into the building. If the school has unit ventilators (uni-vents) in
classrooms, it may not be practical to inspect each unit. Any classrooms or offices that have
elevated radon levels should have the OA supply checked, especially if the room is running
negative in comparison to the outdoors or C 0 2 measurements indicate minimum OA supply.

Classroom C 0 2 measurements should be less than 1000 ppm. This inspection will give a rough
idea of the OA being provided. An actually measurement of the OA being supplied is best done
with a flow hood by a trained technician.
Many schools with unit ventilators have passive relief dampers on the roof. These dampers may
not be providing much resistance to upward stack effect, especially if the school is two or more
stories tall. Designing ASD systems needs to take into consideration the competition from stack
effect when the temperatures get colder.

Outdoor
Air

\

Heating coil

/
b

k

>
k

/

Outdoor
Air
Damper

tunnel or block wall

Filter

Return

If a school has a central HVAC air handler, it may be mining radon if any of the return ducts are
located near radon sources or are depressurizing areas adjacent to the soil. Any return ducts
routed through tunnels, crawl spaces or under slabs need to be carefully inspected. Any
openings in the bottom half of unit ventilators might be mining radon when the units are running.
ASHRAE ventilation standards for schools 62-2001 are as follows:
Classroom 15 CFM per person
Meeting rooms & offices 20 cfrn per person
Gymnasiums 0.6 cfrn per square foot
Libraries 0.3 cfrn per square foot or 15 cfrn per person
Schools built between 1936 and 1975 had a 10 cfrn per person classroom standard
Schools built between 1975 and 1989 had a 5 cfrn per person classroom standard.
Older schools may be providing OA just from windows and leakage. Most schools have some
sort of HVAC system that has either a fixed position damper set 10% open or higher or a
motorized damper that adjusts for each HVAC cycle. Some more sophisticated HVAC systems
may have economizer functions that alter the outdoor air depending upon indoor heat loads and
outdoor temperatures and humidity. Keep in mind that unusual HVAC settings may have been
set that way for good reason.
Many school districts have very tight budgets that cut into HVAC maintenance. Common
problems from inadequate maintenance include clogged filters, OA supplies that are blocked or
fixed to minimum position, broken controls, or freeze protection stats that have tripped into a
minimum OA setting.
As HVAC problems are uncovered it may be best to correct the deficiencies and then re-test.
Sometimes, however, the cost of fixing the HVAC is much greater than installing an ASD
system. ASD systems also tend to be a more permanent fix. Minimum OA, however, still needs
to be provided to the students and staff. Any increases in OA are going to provide a pollutant
reduction equal to the inverse of the OA increase, assuming pressures changes across the shell do
not cause any significant changes. In other words if the outdoor air is doubled, the indoor
pollutant will be half. In general HVAC changes to fix radon levels are usually only practical if
the radon levels are below eight to ten pCi11. For example, if the radon levels were 8 pCi/1 it
would be necessary to have four times as much OA coming into the school to get the new radon
levels to be below 2 pCi/I.

BUILDING CONSTRUCTION CONSIDERATIONS
School foundations are typically slab on grade construction, although there may be individual
mechanical rooms built with basements and sometimes classrooms are built partially below
grade if the building is on a sloped lot. If the slab is placed over a continuous stone based layer,

sub-slab communication might be achieved with only one suction point. Many schools,
however, are built with multiple compartments below the slab that are divided by bearing walls.
Sometimes these bearing walls are just on either side of the main hallway. There can also be
bearing walls between each classroom or office. These bearing walls present two obstacles to
achieving sub-slab communication. The first is the disruption of the sub-slab gravel. The
second is the leakage that takes place at these barriers. Bearing walls made of hollow core
blocks typically extend a few courses below the slab. These walls are often penetrated below
grade by utilities that allow easy airflow into the hollow sections of the block. In addition the
slab often has a half-inch bond breaker material installed between the slab and the foundation
that allows lots of leakage in and out of the sub-slab. There may also be large or small utility
tunnels blocking communication. Block walls that don't penetratethe slab can also block subslab communication if the slab below the wall is thickened by eliminating the sub-slab gravel at
this location.
Along with the problems with bearing walls and slab leakage there is always the issue of what is
under the slab. Although some kind of stone base would be expected in areas of the country
where stone is available, it may be a type that provides limited pressure field extension. One
way to visualize the effect of airflow through different stone bases is to imagine the airflow
through an empty 4" or 6" pipe. Fill the pipe with crushed, clean, 3/4 inch, stone and you can
imagine a reduced but measurable airflow. Now place lots of fines in between the 3/4" stone and
you can imagine how this would reduce airflow. Or imagine the pipe filled with sand. Even
though water will flow through the sand, airflow is highly restricted. Slab on grade commercial
buildings often use a modified fill that has lots of fines.

COMMUNICATION TESTING
Communication testing is using a common shop vacuum to emulate an ASD system by having it
suck on a one to one an a half inch hole through the slab and then measuring the pressure
changes that take place a distances from the suction hole. This test is only done occasionally in
most residential mitigations. In commercial and school buildings it is almost a necessity to
properly design a multiple room ASD system.
The type of shop vacuum used and the size of the suction hole define how much air can be pulled
from beneath the slab. Included is a chart of maximum airflows with different vacuums and
suction holes. Note that the Craftsman and Rigid shop vacuums have about twice as much
airflow through a one and a half inch hole, versus a three quarter inch hole.
Vacuum

0.75" hole 1.0" hole

1.25" hole

1.5" hole

Commercial and school ASD systems can be very high flow situations. It is important to
determine this before the system is installed. It is also important to size the radon fan correctly.
A communication test does not include the performance enhancement provided by sealing of
leaks and digging out of the suction pits. The shop vacuum, however, has a higher capacity
suction, close to 80 inches of water column, compared to the typical maximum vacuum of 2 to 4
inches of water column produced by common radon fans. To better size the final radon system,
a pressure measurement is made at a test hole about 18 inches from the suction hole. This
pressure should be adjusted to create the same pressure that would be created if the suction pit
was dug out and a common radon fan was used. This pressure measurement combined with a
measurement of the shop vacuum airflow can be used to define what size radon piping is needed
and the size of the radon fan. This will also define how many suction holes a single fan system
can effectively handle. In school mitigation systems, it is often more practical to install multiple
fan systems rather than manifold piping between them. See the drawing of a common
communication set up below. To minimize the risk of drilling through sub-slab utilities, study
the "As Built Mechanical Drawings, use a metal scanner, use a metal sensing ground fault, use
common sense.

Run vacuum only long
enough to make
measurements
Use
Micro-manometer
rather than smoke

Measure airflow
with pitot tube

Y4" to 1 !A"
Hole

Test hole
at edge
of future pit

+

318" PFE

Airflow

test hole

The airflow coming out of the suction hole is measured by placing a 2" pvc pipe over the suction
hole and attaching the vacuum hose to the top of the 2" pipe. The velocity pressure in the 2"
pipe is measured with a micro-monometer and a pitot tube. The square root of the velocity
pressure using inches of water column scale is multiplied times 4000 and then multiplied times
the square foot area of the pipe to determine the CFM of air flow.

DETERMINING NECESSARY PIPE SIZES
Once the airflow necessary to achieve adequate pressure field extension is determined, the
necessary pipe size can be deduced using ASHRAE pressure drop tables for air flow in round
pipes. If multiple suction pits are required then the combined airflow needs to be determined
from the point the two or more systems are joined together up to the final exhaust point. The
total pressure drop induced by the piping at the required airflows then defines how powerful the
fan needs to be. Obviously if the pressure drop can be reduced by using larger pipe, the size of
the fan can also be reduced. The maximum airflow achieved with increasing pipe length using
different fans and pipe sizes is depicted in the graph below.

- - - - - - - - - - .,

2 - HP 220's w16" pipe

----

HP 220 w16" pipe

wl6" pipe
- - - - - - .FR--250-8
---. - . -------

- - -- - ------,
- - ---------HP 220 wl4" pipe
----------.
4

-

-

-

-

A

--------

RP 145 wl4" pipe
100.0
50.0

HP 220 w13" pipe

I

- - - - - - . - - -- - - - - - - - - -I - RP 145 wl3" pipe
i
Footage of Pipe

The graph above clearly shows the difference using larger pipe sizes has on airflow. An RP145
uses half as much power as an HP220 fan and yet will move more air in a 4" pipe than a HP220
can move in a three inch pipe.
The chart below obtained from the ASHRAE pressure drop table gives the pressure drop for 100
feet of pipe for different pipe sizes.

Top row is CFM flowing through different pipe sizes

Pressure drop in inches of water per 100 feet of pipe
Along with the pressure drop of the piping there is pressure loss for each elbow or fitting as well
as the pressure drop from the initial suction hole. The chart below gives the approximate
pressure drop for different fittings in equivalent feet of pipe. If four 90 degree sweeps are
included with a four inch pipe run, then multiple the number of fittings times the equivalent feet
from the table below. In this case it would be 4 times 6 equivalent feet and thus 24 equivalent
feet would be added to the actual pipe footage. Note that a sharp elbow, which is an elbow that
makes a sharp edge turn, has more than double the resistance of a sweep elbow.
Pipe Sweep Sharp Sweep Sharp
Reducer Pipe
end
size
45O
90'
90Â
45O
5'
2'
3"
3'
11'
19'
17'

For each length of pipe find the pressure drop for its size and the airflow flowing through it.
Then multiple the 100 foot pressure drop by the length of the pipe divided by 100. Add up these
pressure drops from the exhaust to the first suction point or tee fitting to get the total pressure
drop. The fan needs to be able to produce the necessary airflow and pressure required in the
suction pit with the added resistance of the piping. Lets assume a proposed simple system has a
total equivalent length of 150 feet of four inch piping and the airflow required is 80 cfm, A final
pressure of 0.8 inches of water column was necessary in the suction hole. The four inch pipe
loss at 80 cfm, which is 0.4 inches, would be multiplied by 1.5 (1 50 divided by 100) times. This
would give a total piping pressure drop of 0.6 inches and a required pressure of 0.8 inches for a
total pressure of 1.4 inches at 80 cfm. A RP145 fan can just about provide this performance as
seen in the fan chart below.

Fan Performance Curves

I

GP501 13 amos

'

RPW5 0.5 amps

CFM

OTHER DESIGN CONSIDERATIONS
School classrooms are typically fire-rated between the classroom and hallways, adjoining rooms
and any rooms above or below the classroom. No flammable materials such as PVC piping are
allowed to be installed in any return ducts. The fire marshal needs to be consulted during the
design phase to ensure compliance with all fire code regulations.

CONCLUSION
Schools can often have complicated HVAC systems that require expertise beyond what a
mitigator might provide. A team approach is often needed. The size of the school and the
typical construction features of schools requires obtaining more information to careful design a
radon system than would be required to mitigate a residential building.

REFERENCES
Radon Measurement in Schools
EPA 402-R-92-0 14 July 1993
Radon Prevention in the Design and Construction of Schools and Other large Buildings
EPA 625-R-92-0 16 January 1993
Reducing Radon in Schools: A Team Approach
EPA 402-R-94-008 April 1994