Air Admittance Valves
Q. How does the Studor Air Admittance Valve
work?
A. The Studor Air Admittance Valve (AAV) is a one-way
valve that allows air to enter the plumbing drainage
system when fixtures discharge. The valve closes by
gravity when discharge is completed and under no flow
conditions preventing sewer gas from escaping into the
valve.
Q. Why is it important to allow air to enter the
plumbing system?
A. When fixtures discharge negative pressure develops in
the drainage system due to water flowing downstream in
the pipes. If air does not enter the system and balance
the pressure the water in the fixture trap will be
siphoned allowing sewer gas to enter the building.
Q. Are Studor Air Admittance Valves suitable for all
applications?
A. YES! Studor manufactures various models which fit
pipe sizes of 1 1/2", 2", 3" and 4". The valves are
suitable for single fixtures, branches and stack
applications in residential and commercial buildings.
Q. Can Studor Air Admittance Valves be used in extreme
temperatures?
A. All Studor Air Admittance Valves are tested to temperatures of -40° F
and +150° F as required by the ASSE Performance
Standards. In addition some models are provided with
insulation material as part of the packaging which
provides additional protection.
Chem-Vent FAQ
Q. What is a Chem-Vent?
A. The Chem-Vent is a specialty Air Admittance Valve
(AAV) manufactured by Studor.
Q. What is its intended purpose?
A. The Chem-Vent was purposely designed to be used in
specialized acid waste systems as a replacement of
conventional vent pipes and loop vents (very commonly
used in lab style layouts).
Q. What kind of acid waste systems?
A. The kind commonly installed in schools, hospitals and
labs in general.
Q. Can the valve be used in systems handling
bio-hazardous or otherwise toxic waste?
A. The valve CANNOT be used in
any applications where the fumes contained in the waste
systems would require filtration before humans could be
exposed to them.
Q. Can any material Air Admittance Valve be used in acid waste
systems?
A. No, technically, only the Chem-Vent since all its
components are designed to handle the corrosive and
temperature environment of an acid waste system.
Standard (residential or other commercial) Air Admittance Valves have
neither the chemical resistance nor the temperature
range to operate in such systems.
Q. Is the use of the Chem-Vent in acid waste
systems code approved?
A. Currently the plumbing codes do not allow the use of
any Air Admittance Valves in an acid waste system. This application was
correctly excluded in the codes because no manufacturer
produced a suitable product. Studor’s Chem-Vent is
different and Studor is working with the code
authorities to make an exception for Air Admittance Valves manufactured
from chemical- and acid-resistant material.
Q. Can the Chem-Vent be used before the code
language is changed?
A. Even before the code is changed it will be possible
to use the Chem-Vent as part of an engineered system.
Q. What makes the Chem-Vent different from all
other Air Admittance Valves?
A. Its Flame Retardant Polypropylene (FR-PP) material of
construction and its chemical resistance EPDM seat.
Q. Why FR-PP?
A. For the last 20 years FR-PP has been the material of
choice in the vast majority of institutional lab
installations (e.g. schools, hospitals, etc.)
Q. Are there any other material used in acid
waste systems?
A. Yes, starting from the oldest to the newest:
• Ductile Iron (Duriron®)
• Borosilicate glass
• FR-PVDF
• CPVC
Q. When, where and why are these materials used
instead of FR-PP in Acid Waste piping systems?
A. Duriron was the very first system used in acid waste
system before better materials came along. Its chemical
resistance is very poor and so is its life expectancy.
The Chem-Vent can be comfortably specified and used on
any Duriron systems.
• Glass replaced Duriron as the material of choice and
is still extensively used today in return air plenum
applications as well as with some extreme chemicals.
Cost, limited jointing styles, brittleness and
difficulty of installation of glass have allowed FR-PP
to become the predominant choice. If FR-PP is deemed
resistant to the chemical waste in a glass system, the
Chem-Vent can be used on glass systems unless the system
is installed in a return air plenum.
• FR-PVDF is a relatively new material designed
specifically to replace glass in return air plenum
installations. Although comparable in material cost its
versatility, light weight and available jointing systems
makes the installed cost of FR-PVDF systems in return
air plenum very competitive with glass. If FR-PP is
deemed resistant to the chemical waste in a glass
system, the Chem-Vent can be used on glass systems
unless the system is installed in a return air plenum.
• CPVC is the newest material in acid waste system. Like
FR-PP it cannot be used in return air plenum
applications; additionally it cannot be used if solvents
are part of the waste flow. Thanks to its proven solvent
cement jointing system CPVC is easy to install and does
not require specialty equipment. The Chem-Vent can be
comfortably specified and used on any CPVC systems.
Q. How does the Chem-vent connect to an FR-PP
system?
A. The valve’s extended tail piece can be directly
installed on any mechanical joint or fusion sanitary Tee
currently available (regardless of the manufacturer)
following the acid waste system manufacturer jointing
instructions.
Q. How can the Chem-Vent be installed on
dissimilar material systems?
A. Through adapters designed to transition from FR-PP to
glass, ductile iron or CPVC.
Q. Where can I find these adapters?
A. FR-PP to glass or ductile iron adapters are readily
available through the different FR-PP piping system
manufacturers. FR-PP to CPVC adapters are readily
available through the different CPVC piping system
manufacturers.
Q. Why does the Chem-Vent have an extended tail
piece connection?
A. To make sure that the vent will always comply with
the code required minimum of 4” above the trap, no
matter which FR-PP manufacturer or system is selected.
Q. Does the Chem-Vent meet any performance
standards?
A. Yes the Chem-Vent is tested to and certified to; NSF
14
Maxi-Filtra FAQ
Q. What is a Maxi-Filtra?
A. The Maxi-Filtra is a device that serves as a two way
vent that allows air to pass through a carbon filter and
eliminate sewer gas odors.
Q. Can the Maxi-Filtra be use indoors?
A. No, the Maxi-Filtra is designed for outdoor use only,
particularly for use with septic systems.
Q. Can the Maxi-Filtra be installed
horizontally?
A. Yes, the Maxi-Filtra can be installed in the
horizontal or the vertical position.
Q. Can the Maxi-Filtra be installed in an
existing system?
A. Yes, the Maxi-Filtra can be retro-fitted on an
existing system.
Q. How long does the carbon filter cartridge
last?
A. The cartridge can last up to 2 years.
Q. Does the Maxi-Filtra require maintenance?
A. No maintenance is required other than replacing the
cartridge.
Q. Is the Maxi-Filtra protected from UV rays?
A. Yes, there is also an optional cover available for
additional protection.
Q. What size pipe does the Maxi-Filtra fit?
A. The Maxi-Filtra fits a 3" or 4" pipe.
P.A.P.A. FAQ
Q. What does P.A.P.A. stand for?
A. Positive Air Pressure Attenuator
Q. What is the P.A.P.A. used for?
A. It is used to neutralize positive air transients in
the DWV system of multi-story buildings.
Q. What is a Positive Air Transient?
A. It is a low amplitude, high speed air pressure wave
traveling through the system.
Q. How fast does it travel?
A. 1056 ft/sec - the speed of sound.
Q. Does it represent a large volume of air?
A. No, typically it is no more than 1/2 gallon of air.
It can, however, be greater depending on conditions.
Q. Why are Positive Air Transients created into
a DWV system?
A. Fluids discharged into a DWV system, after reaching
terminal velocity, begin to swirl inside the pipe,
dragging air into the center of the pipe. After the pipe
transitions from vertical to horizontal (bottom of the
stack or change of directions) a curtain of water is
formed. The air hitting this curtain bounces off of it
and travels backward through the system.
Q. Are Positive Air Transients the only
potential for positive air pressure in a DWV system?
A. No, positive pressure can also travel into a
buildings DWV system from sewer (or septic tank) or be
generated by a blockage(or belly in the pipe).
Q. Is the P.A.P.A. designed to neutralize all
positive air pressure conditions?
A. No, just Positive Air Transients.
Q. Why are Positive Air Transients harmful to a
DWV system?
A. They can result in the loss of water seals or, at a
minimum, contribute to the depletion of the traps.
Positive air transients ave been proven to resonate
inside of conventionally designed systems up to three
days. In addition they can be the source of bubble
through; a condition that allows sewer gases as well as
pathogens to be introduced in to the living space
without loss to the trap seal.
Q. How are Positive Air Transients typically
dealt with?
A. Relief Vent
Sovent System - This system
deals indirectly with the positive air transient slowing
down the flow in the system thus preventing terminal
velocity to be reached. Special aerator and de-aerator
fittings must be used at each branch in order to prevent
the formation of positive transients.
Single Stack system -
(Philadelphia system) - The Single Stack system relies
on venting through the roof, with consequent increased
roof penetrations.
Q. Is a P.A.P.A. / Air Admittance Valve system better than these
other systems and if yes, why?
A. Technically it is better for four reasons: • System
balancing in 0.2 seconds
• Neutralize almost 100% of the transient
• Eliminates floor and roof penetrations
• Maintains the natural flow in the system
In addition, it also represents substantial savings over
the other designs.
Q. Why would most of the transient naturally
flow in into the P.A.P.A. if it is attached to a smaller
branch, much like a relief vent?
A. Because the instant a minimal portion of the
transient begins to inflate the P.A.P.A. bag a
differential pressure is created at the branch-off point
making the branch and the P.A.P.A. the path of least
resistance for the air.
Q. What happens to the air transient once it
enters the P.A.P.A.?
A. Its velocity (1056 ft/sec) is instantly (less than
0.2 sec) cut to 40 ft/sec after which the small (and now
slow) air volume is harmlessly re-introduced into the
system.
Q. What if it is determined that there is the
potential for a greater than average air volume?
A. Up to four P.A.P.A.'s can be serial mounted for up to
a total volume capacity of 4 gallons.
Q. Is the P.A.P.A. a maintenance item?
A. No, it does not require maintenance since there are
no stress pieces, springs or mechanical devices that
could wear or lose tension and consequently fail.
Q. What kind of warranty does it carry?
A. The P.A.P.A. has a limited lifetime warranty for
replacement of defective product.
Q. Must the P.A.P.A. be installed vertically?
A. No, it can be mounted in any position and orientation
(unless used with an Air Admittance Valve on top)
Q. Where should the P.A.P.A. be installed?
A. It should be installed at the bottom of each stack in
the building below the first branch and before the sweep
transitioning the pipe from vertical to horizontal.
Additional units may be required on each stack,
depending on the number of branches (see our
installation guide)
Q. Can the P.A.P.A. be retrofitted to an open
pipe vent system?
A. Yes
Q. Can it be engineered as an integral part of
an open pipe vent system as additional protection?
A. Yes
Q. What can the P.A.P.A. be compared to in order
to give customers a quick understanding of its function?
A. In essence, the P.A.P.A. performs a function similar
to that of a water hammer arrestor, but for air.
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