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Home Energy Magazine Online March/April 1996
Mechanical Ventilation for the Home
by Don Stevens
Don Stevens is a ventilation consultant in
Keyport, Washington.
A ventilation system gives occupants control
over a home's air change rate and thermal comfort. This article discusses
the options available today for good mechanical ventilation.
All houses
and apartments need an efficient way to exhaust stale, moist indoor air
and introduce outdoor air. Good ventilation makes a house healthier for
occupants and protects the building structure from moisture damage (see
"Fundamentals of Moisture in Houses," HE
Nov/Dec '95, p.11).
Traditionally, home builders have relied on "natural
ventilation" and infiltration provided by random gaps and cracks in the
building shell. The occupants can control ventilation in these houses only
by operating the windows and doors. Natural ventilation depends on wind
speed and temperature differences between indoors and outdoors. A house
that "breathes" on its own often has too much ventilation in the winter,
resulting in high heating bills and uncomfortable drafts. On mild or calm
days in other seasons, the house often has too little ventilation.
Houses built today are tighter than houses of
50 years ago, while the number of pollutants in the home has grown (although
smoking is less prevalent). Choosing less toxic building materials at the
design stage can limit pollutants in a new home, but this option isn't
available once the home is built. Fireplaces, wood stoves, and other combustion
appliances increase pollutant levels. Moisture, pets, furnishings, cigarette
smoke, aerosol sprays, household cleaners, and hobby supplies add to the
mix.
A well-designed mechanical ventilation system
with good controls is important to provide consistent ventilation through
all seasons of the year for all housing. Fans exhaust stale air. Leaks,
passive inlets, or another fan draws in outdoor air. Maintaining good indoor
air quality in a house requires reducing pollution sources and providing
adequate ventilation to remove and dilute pollutants.
In warm climates, good indoor air quality may
be achieved with supply ventilation, but most systems described here deal
with exhaust ventilation for temperate and cold climates.
Ventilation Codes
Code requirements for ventilation systems vary in
different jurisdictions and utility programs. The local building department
is the best source of information on specific code requirements for an
area. This article addresses good practices that meet the ventilation standard
set by the American Society of Heating, Refrigerating, and Air Conditioning
Engineers (ASHRAE).
Most building and ventilation codes and utility
programs in the United States are based on ASHRAE 62. (ASHRAE develops
guidelines and standards for engineering design, building practice, and
building codes throughout the United States.) ASHRAE Standard 62-1989,
Ventilation for Acceptable Indoor Air Quality, requires mechanical spot
ventilation for specific sources of indoor pollutants. It also requires
general ventilation that operates whenever the house is occupied to maintain
indoor air quality. The number of occupants determines the amount of general
ventilation required. Let's look at these two types of ventilation.
Types of Ventilation
Spot ventilation removes moisture, odors, and pollutants
directly at the source. ASHRAE requires a ventilation rate of at least
50 cubic feet per minute (CFM) for a bath fan. If the fan is operated continuously,
a reduction to 20 CFM is allowed. A kitchen ventilation fan over or near
the stove with a minimum flow of 100 CFM is required for removing cooking
fumes; a 25-CFM pickup is allowed if the fan is operated continuously.
Spot ventilation fans must be vented to the outside.
General indoor air quality (IAQ) ventilation
removes contaminants and delivers outdoor air to the occupied rooms of
a house. The current ASHRAE standard recommends a minimum of 0.35 air changes
per hour (ACH)-that is, in one hour 35% of the home's air is exhausted
and replaced with outdoor air. A proposed revision to the ASHRAE 62 standard
uses 5 CFM per 100 ft2 of household area as a simpler calculation method.
In either case, the ventilation rate must be not less than 15 CFM for each
occupant, assuming two occupants for the master bedroom and one for each
additional bedroom. I recommend that the ventilation installer use 0.5-0.6
ACH for an upper limit on ventilation rate.
The ASHRAE standard does not require mechanical
ventilation, but we know from blower-door and tracer-gas testing that only
mechanical systems provide outdoor air reliably through all seasons.
Ventilation Approaches
Most builders use one of four approaches to provide
spot and general IAQ ventilation (see Table 1 for a
summary of advantages and disadvantages of each approach). Notice that
none of these systems relies explicitly on cracks and gaps in the house
for outdoor air. Each ventilation system includes an exhaust fan and a
way to bring outdoor air into the house either passively or mechanically.
| Table 1. Pros and Cons of Different Ventilation Systems |
| System Type |
Pros |
Cons |
|
| Double-duty fan |
Most familiar; least expensive |
Use of timer; must undercut doors |
| Dedicated fan |
Central location; no bathroom doors undercut |
Additional fan cost; use of timer |
| Ducted central exhaust fan |
Quietest operation; one roof penetration; least wiring |
Unfamiliar concept; uses more ducting |
| Heat recovery ventilation |
Tempers and filters incoming air; quiet operation; cost
savings in expensive/cold areas |
Expensive installation; defrost needed; condensate drain
needed; no savings in temperate areas |
| Ventilating heat pump water heater |
Heats most of water with waste heat |
Unfamiliar concept; expensive installation; condensate drain
needed |
| Dehumidifying ventilator |
Dehumidifies and filters inside and out |
Unfamiliar concept; expensive installation; condensate drain
needed |
Double-Duty Fan
A single bath or laundry room fan, centrally located,
acts both as a spot ventilator for the bathroom or laundry room and as
the general IAQ ventilation fan. A switch, interval timer, humidity control,
or occupancy sensor controls the fan for spot ventilation. A 24-hour clock
timer wired to the fan provides automatic general ventilation. Occupants
schedule ventilation times. Both individual controls and integrated sensors
are available from American ALDES, Broan, Grasslin, Intermatic, NuTone,
Tamarack Technologies, and Tork (see Table 2). These
fans may sense humidity, carbon dioxide, cigarette smoke, or motion.
The fan should be quiet, with a sound rating
of 1.5 sones or less. Most bath fans are rated at 3 to 4 sones and are
too noisy for the extended operation needed for a general IAQ ventilation
fan (see Table 3 for a list of quiet, low energy fans).
Panasonic has set the quiet fan standard, with several 0.5- and 1.0-sone
fans. Other manufacturers are introducing new fans to try to catch up.
| Table 2. Fan, HRV, and Control Manufacturers |
| Manufacturer |
Phone Number |
Products Available |
| American ALDES Ventilation Corporation |
Tel:(800)255-7749 |
CM, DH, RS, T&C, WP |
| Broan Manufacturing Company |
Tel:(800)558-1711 |
CM, HRV, RS, RM, T&C, WP |
| Carrier Corporation |
Tel:(800)227-7437 |
HRV |
| Continental Fan |
Tel:(800)320-0504 |
RS |
| Crispaire Corp/E-Tech division |
Tel:(404)458-6643 |
VHP |
| DEC International/Therma-Stor Products Group |
Tel:(800)533-7533 |
DH, RS, RM, T&C, VHP, WP |
| Duro Dyne Corporation/DuroZone division |
Tel:(800)899-3876 |
T&C |
| Fan America |
Tel:(800)838-4074 |
CM, RM |
| Fantech |
Tel:(800)747-1762 |
RS, RM |
| Honeywell |
Tel:(800)328-5111 |
HRV, T&C |
| Grasslin Controls Corporation |
Tel:(914)664-3542 |
T&C |
| Intermatic Incorporated |
Tel:(815)675-2321 |
T&C |
| NuTone Incorporated |
Tel:(800)543-8687 |
CM, T&C |
| Panasonic |
Tel:(201)348-7231 |
CM, T&C |
| RAYDOT Incorporated |
Tel:(800)328-3813 |
HRV |
| Stirling Technology Incorporated |
Tel:(800)535-3448 |
HRV |
| Tamarack Technologies Incorporated |
Tel:(800)222-5932 |
CM, HRV, T&C |
| Tork |
Tel:(201)825-9696 |
T&C |
| Venmar/VanEE |
Tel:(800)667-3717 |
HRV |
| CM |
Ceiling-mounted fans |
RM |
Remote-mounted multiport fans |
| DH |
Dehumidifying ventilator |
T&C |
Timers and controls |
| HRV |
Heat recovery ventilator |
VHP |
Ventilating heat pump water heater |
| RS |
Remote-mounted single-port fans |
WP |
Wall inlet ports |
| Table 3. Quiet Fans Suitable For General IAQ Ventilation |
| Ceiling-Mounted Fans |
CFM @ 0.1"wg |
CFM @ 0.25"wg |
Fan Input Wattage |
HVI Sound Rating |
Fan Efficiency |
| American ALDES CMV80 |
80 |
55 |
32W |
0.8 sones |
.03-.05 |
|
| American ALDES CMV100 |
95 |
75 |
34W |
1.2 sones |
.03-.06 |
| American ALDES CMV125 |
120 |
105 |
40W |
1.5 sones |
.04-.08 |
| Broan S90 |
90 |
75 |
50W |
1.5 sones |
.02-.04 |
| Fan America SMV80 |
80 |
60 |
35W |
0.8 sones |
.03-.05 |
| Fan America SMV100 |
100 |
82 |
37W |
1.2 sones |
.03-.06 |
| Fan America SMV140 |
120 |
110 |
40W |
1.5 sones |
.04-.08 |
| NuTone QT80 |
80 |
63 |
47W |
1.5 sones |
.02-.04 |
| NuTone QT90 |
90 |
85 |
50W |
1.5 sones |
.02-.05 |
| NuTone QT100L |
100 |
80 |
30W |
1.5 sones |
.04-.08 |
| NuTone LS50 |
50 |
23 |
16W |
0.3 sones |
.04 |
| NuTone LS80 |
80 |
55 |
24W |
0.8 sones |
.04-.07 |
| NuTone LS100 |
100 |
80 |
33W |
1.5 sones |
.04-.07 |
|
| Panasonic 05VQ |
50 |
31 |
12W |
0.5 sones |
.05-.08 |
| Panasonic 07VQ |
70 |
52 |
15W |
0.5 sones |
.05-.10 |
|
| Panasonic 08VQ |
90 |
70 |
17W |
1.0 sones |
.06-.12 |
|
| Panasonic 11VQ |
110 |
88 |
19W |
1.5 sones |
.07-.14 |
| Panasonic 20VQ |
190 |
130 |
31W |
1.5 sones |
.07-.12 |
| Remote Single-Point Inline Fans |
CFM @ 0.4"wg |
Fan Input Wattage |
Fan Efficiency |
| American ALDES SPV200 |
75-230 |
125W |
.03-.22 |
|
| Broan SP100 |
97 |
50W |
.09 |
| Broan SP140 |
141 |
85W |
.08 |
| Continental AXC100A |
85 |
35W |
.11 |
| Continental AXC125A |
80 |
40W |
.09 |
| Fantech F/FR100 |
90 |
70W |
.06 |
| Fantech F/FR125 |
110 |
70W |
.07 |
| Rosenburg R100 (DEC) |
83 |
50W |
.08 |
| Remote Multipoint Fans |
CFM @ 0.4"wg |
Fan Input Wattage |
Fan Efficiency |
| American ALDES VMP-S |
65-130 |
75W |
.04-.08 |
| American ALDES VMP-K |
100-180 |
80W |
.06-.11 |
| American ALDES MPV200 |
75-230 |
90W |
.04-.12 |
| American ALDES MPV300 |
200-330 |
120W |
.08-.13 |
| Broan MP100 |
98 |
50W |
.09 |
| Broan MP140 |
141 |
85W |
.08 |
| Broan MP200 |
200 |
140W |
.07 |
| DEC Quiet Vent |
165-295 |
120W |
.06-.12 |
| Fantech CVS 275 |
230 |
115W |
.09 |
| Notes:
(1) The flow, input wattage, and sound ratings are manufacturers' data
provided to the author.
(2) Home Energy calculated the fan efficiencies from the input wattage
and the flow at the two static pressure points provided.
(3) There are no sound ratings currently available for remote single-point
or multipoint fans, but these fans are generally relatively quiet in application
because the fan motor is located away from the living space. |
Dedicated Fan
A centrally located, quiet ceiling fan acts as the
general IAQ ventilation fan. Often it is located in the hall or at the
top of the stairs. All spot ventilation is handled by other fans. A 24-hour
clock timer is wired to the fan so that occupants can schedule ventilation
times.
The dedicated fan should be quiet enough not
to disturb occupants, especially if it is located near bedrooms. Generally
a sound rating of 1.5 sones will be acceptable, but the quieter the fan,
the less likely it is that residents will complain. Fans rated at 0.5,
0.8, and 1.0 sones should be considered, since people aren't used to having
a fan run for extended periods.
Pictured here is the remote (main) unit for a multi-point
exhaust fan system. With pick-ups in several locations, this single-motor
system provides quiet ventilation throughout the house. |
Ducted Central Exhaust Fan
A remote-mounted central exhaust fan serves as the
general IAQ fan; often it is installed in the attic or basement. It may
be an inline fan with a single pickup or a multipoint fan with 3 to 6 pickups
(see "Bathroom Exhaust Fans,"
HE
Nov/Dec '95, p. 29). It may provide spot ventilation from one or more locations
in addition to providing the general ventilation. Remote-mounted fans have
the advantage of reducing noise in the house. With no ceiling-mounted fans,
all the occupant hears is air noise at the grille. Bathrooms, laundry rooms,
and spa rooms that are not connected to the central system have conventional
spot ventilation fans, but generally the central fan is sized to pick up
all the ventilation locations. Two control strategies may be used:
-
A 24-hour clock timer controls the fan for intermittent
general ventilation, with interval timers (manual spring-wound timers)
wired at spot ventilation locations to override the central timer.
-
The central fan operates continuously at a low rate
to meet both the spot ventilation rate and the general IAQ rate. In this
case, no controls are needed.
This remote single-point fan can be used for quiet
bathroom exhaust, make-up air supply, or clothes dryer or range hood boosting. |
Heat Recovery Ventilation
Heat recovered from stale exhaust air can be used
either to heat incoming ventilation air or to make hot water. A heat recovery
ventilator typically recovers 60%-75% of the waste heat in the exhaust
air from the house and sometimes from the spot ventilation fans.
Although most places in the United States are
not cold enough or do not have utility rates high enough to make them cost-effective,
heat exchangers have other advantages. They filter fresh air coming in
and temper it for comfort, and they better balance the flow of incoming
fresh air and exhausted stale air.
A traditional heat recovery ventilator (HRV)
or energy recovery ventilator (ERV) generally uses a fixed plastic or aluminum
core or a rotating plastic wheel to move heat from the stale exhaust air
to the incoming fresh air. An HRV transfers mostly sensible heat, while
an ERV can recover additional heat, due to the latent heat of moisture
transfer. The colder the climate, the more energy is saved by warming the
incoming ventilation air. The HRV can also be used in warm climates to
precool outdoor air, to reduce the air conditioning load. However, the
designer should make sure that the heat exchanger has the ability to accommodate
moist air without causing condensation problems. Exhaust ducts run from
pickup points in bathrooms and in the living space to the HRV unit. Supply
ducts to the main living space and the bedrooms or to the furnace ductwork
deliver the tempered outdoor air to the occupied spaces. Supply and exhaust
ducts are run from the HRV unit to the outside. Generally two fans operate
within the HRV cabinet to bring in outdoor air and exhaust stale indoor
air. Look at and compare the efficiency ratings by the Home Ventilating
Institute (HVI) when considering HRV equipment.
An HRV unit is usually either controlled by a
24-hour timer or operated continuously. Some units have two or more ventilation
speeds, and most offer defrost capability to keep surfaces from frosting
up in cold weather. A ducted range hood provides spot ventilation in the
kitchen, since grease from cooking should not be pulled into the HRV ducts.
Avoiding Backdrafting
Care should be taken to avoid backdrafting combustion
appliances with negative pressure from ventilation fans. While the general
IAQ system should be run for long periods, higher-CFM fans, such as range
hoods, downdraft range exhausts, and dryers, will often cause larger problems
with carbon monoxide (CO) and other contaminants. Gas water heater pilot
lights and even supposedly airtight wood stoves with outside-combustion
air can be backdrafted at only 2-4 Pa of negative pressure. The best strategy
is to use only sealed combustion appliances and to avoid wood stoves and
fireplaces. If the presence of combustion appliances makes backdrafting
a concern, avoid large spot exhaust fans, use balanced-flow ventilation
with HRVs or blending ventilators, and install a CO detector. Houses will
virtually always go negative under certain conditions, even if a balanced-flow
system is installed. |
A ventilating heat pump water heater (VHPWH) uses
a small dedicated heat pump to recover heat from ventilation exhaust air
and transfer it to a hot water tank. The fan on the VHPWH unit acts as
the general ventilation fan; ventilating eight hours a day, the VHPWH can
generally make all the hot water needed for a typical family of four from
waste heat in the exhaust air. This unit is different from a heat pump
water heater sitting in a room, since the fan must be capable of pulling
stale air from several rooms and of exhausting the stale air outside. In
a cooling climate, the air flow for some units can be reversed in the summer
to cool and dehumidify incoming outdoor air as a supply ventilator. Exhaust
ductwork is run from one or more pickups in the house to provide general
IAQ ventilation and possibly some spot ventilation. Outdoor air is introduced
into bedrooms and living spaces through vented windows or wall vents. A
ducted range hood provides spot ventilation in the kitchen. Bathrooms,
laundry rooms, and spas that are not connected to the VHPWH system have
conventional spot ventilation fans. At least two companies offer VHPWH
units in the United States-DEC Therma-Stor and E-Tech.
A dehumidifying ventilator uses a small compressor
to dehumidify and reheat the indoor air while introducing outdoor air to
blend with it. This supply-side ventilator can be operated either as a
positive-pressure system by itself in warm climates or as a balanced-flow
system in cold climates if a quiet, low-energy fan is used to exhaust a
like amount of indoor air. It includes a high-efficiency air filter to
clean the blended air to near-HEPA quality. (HEPA stands for High Efficiency
Particulate Arrestor. It is a filter capable of filtering out 99% of particles
1 micron or larger. The filter on the dehumidifying ventilator removes
95% of particles 1 micron or larger, so it is called "near HEPA.") This
type of ventilation can be used in areas of medium to high temperatures
and high humidity to dehumidify and clean the indoor air efficiently, while
introducing outdoor air. When it is relatively cool but humid, as at night,
it will dehumidify the air and improve comfort even when the air conditioner
does not get a call for cooling. Dehumidifying ventilators are available
from American ALDES and DEC Therma-Stor.
Compact Fluorescent Fan/Light Coming Soon
In the spring of 1996, a compact fluorescent light
option will be available on Panasonic's 70, 90, and 110 CFM quiet ventilation
fans. This new fan/light combination will use a separate ballast and two
13W lamps to provide a fan and light with a combined draw as low as 41W,
rather than the 150W-200W of a conventional fan/light. It is designed for
both new construction and retrofit. |
Meeting Outdoor Air Requirements
The amount of outdoor air being brought into the
house should equal the general IAQ ventilation rate discussed earlier (0.35-0.50
ACH or 5 CFM per 100 ft2, but not less than 15 CFM per person).
Outdoor air can be supplied in several ways.
Wall or window vents must allow air to flow at
low pressures and should be tested according to the HVI test standard.
(The HVI is the same organization that certifies the air flow of fans and
the efficiency of HRVs.) Field testing shows that only a small portion
of the outdoor air that comes into the structure actually passes through
these vents. The use of the vents, however, ensures that at least some
of the outdoor air is introduced into the spaces that most need fresh air,
such as bedrooms.
One way of supplying outdoor air to a house, wall
vents should be positioned high on walls and away from seating areas and
beds, since they may produce drafts. |
Wall vents are generally made of plastic and/or
metal and include a rain cap for the outside, an insect screen, and a cleanable
filter. They also include a flow control mechanism to limit or stop air
flow, a liner to pass through the wall cavity, and a device to direct the
airstream away from people in the room. Wall vents should be located high
on the wall and away from seating areas and beds, to minimize complaints
about drafts. European products manufactured for this purpose have been
used throughout the United States for several years. They are available
from American ALDES (Airlet models 100 and 200) and DEC Therma-Stor (FRESH
80 and FRESH 100).
Window vents are generally located in the upper
sash area of the window. They usually have a rain shield and an insect
screen, but no filter. Occupants can control the air flow by opening and
closing the vent. The design may be as simple as drilled holes in the vinyl
frame with a sliding shutter. Window vents vary in size, but they all must
be tested in accordance with the HVI procedure. Depending on the manufacturer,
the upper "sight line" of the window may be affected, since the vent can
make the frame taller. Many vinyl and aluminum and some wood window manufacturers
now offer vented windows. Window vents are manufactured by Titon Incorporated
and American ALDES.
Instead of wall or window vents, some systems
use an outdoor air connection to a furnace return air plenum. The connection
should be between 6 and 8 inches in diameter to reduce pressure drop, depending
on the flow required. In the Pacific Northwest, we require that the duct
be a minimum of 6 inches for up to 80 CFM, 7 inches for 80-120 CFM, and
8 inches for 120 CFM or more, assuming up to 20 ft of run from the outside.
For best operation, a motorized damper should be used to limit the intake
of outdoor air to periods when the exhaust fan is being operated for general
IAQ ventilation. Otherwise the furnace will pressurize the house if the
IAQ fan is off. The furnace air handler must also be turned on for circulation
and to draw in the outdoor air. Honeywell and DuroZone both make controllers
that turn on the air handler and the exhaust fan and open the motorized
damper.
Although connecting to the furnace is relatively
simple, using a 400W air handler fan motor to pull in outdoor air and circulate
it wastes a lot of energy compared to a low-energy fan, such as Panasonic's
15W 70 CFM model. The furnace fan strategy would increase electrical consumption
by over 1,000 kWh per year. (Using a variable-speed furnace fan would reduce
the fan motor's energy use, but the pressure in the return air plenum-necessary
to bring in fresh air-would be reduced even more, making it ineffective.)
Window vents allow occupants to control air flow by
opening and closing the vent located in the upper sash area of the window.
While separate vent units have been most common in the past, some manufacturers
now offer vented windows. |
Sizing Fans
Most bath fans are designed to provide at least
50 CFM. Whenever ducts, grilles, wall caps, or roof caps are connected
to a fan, the fan has to work harder to move air. Fan flow ratings are
based on a particular amount of resistance to air flow, described as static
pressure. Most bath fans are rated at 0.1 inches of water gauge (also known
as water column), often abbreviated as 0.1 wg. This is roughly the pressure
drop created by 50 CFM of flow through a grille, 5 ft of 3-inch flex duct,
and a wall cap for the fan. Bath and range hood fans have been tested and
certified by the HVI at flow ratings of 0.1 wg and sometimes at 0.25 wg.
The product literature for many fans includes a table with the fan flow
rates at a variety of static pressures.
Most actual duct installations are longer than
5 ft and/or have elbows, which makes the resistance greater than the HVI
test assumes. To compensate for duct resistance, many utility programs
and building codes require that the fan's air flow be rated at a higher
static pressure than 0.1 wg, or that the fan be increased in size (flow
rate). For example, the State of Washington's ventilation code requires
that the fan's flow be certified at 0.25 wg. It's best to plan on using
the flow at 0.25 wg to meet required flow, since this is more likely to
be the typical static pressure when fans are installed.
Ducts and
Terminal Devices
Ducts need to be sized correctly to deliver the
desired air-flow rate. Flexible duct has about twice as much resistance
to air flow as smooth metal duct, but either type can usually be used for
bath fans. When using flex duct, keep runs short. Avoid droops that increase
resistance and create a place for moisture to condense. Avoid using plastic
dryer duct connectors. Use at least 4-inch ducts for fans of less than
80 CFM and 5-inch ducts for fans up to 120 CFM. Flex duct is acceptable,
but smooth duct provides better air flow. For kitchen range hoods, only
smooth metal duct meets the Uniform Mechanical Code and other model codes.
All duct joints, fittings, and adjustable elbows need to be sealed with
duct mastic or high-quality duct tape.
All fan ducts need to terminate outside the building
shell-not in an attic or a soffit, or under the house. With a solid duct
connection, moisture is carried outside the building shell so that it cannot
condense inside a wall or on the bottom of the roof. Exhaust ducts should
connect directly to a collar that extends through the wall or ceiling to
a termination designed for exhaust air flow.
ASHRAE Standard Revisions
The 1996 revision to the ASHRAE ventilation standard
currently under review will define and require ventilation systems to be
capable of providing "continuous ventilation," which I have labeled general
IAQ ventilation in this article. This type of ventilation is also known
as whole house ventilation in the Pacific Northwest. The draft revision
includes three methods of providing continuous ventilation. While ASHRAE
does not define the sound level for continuous-ventilation fans, it does
require that fan sound be addressed.
HVI plans to define fans for "continuous ventilation"
as fans with a sound rating of 1.5 sones or less if ceiling mounted. HVI
is developing a sound testing standard for remote-mounted fans. It is advisable
to use sound-absorbing ducting with an HRV, a blending ventilator, or a
remote-mounted fan to ensure quiet operation. (A blending ventilator tempers
outside air with house air to make the air flow somewhat more comfortable
without using a heat exchanger.) The continuous ventilation fan will be
required to have a certified flow rating at 0.25 wg for ceiling-mounted
fans and 0.4 wg for remote-mounted fans and HRVs.
|
Timers and
Other Controls
For effective ventilation, the general ventilation
fan needs to operate when contaminants are present or are being produced.
The ASHRAE standard recommends ventilation whenever the house is occupied.
Generally, a good compromise in practice is to ventilate 8 to 12 hours
a day. Ventilation can be scheduled by using a 24-hour timer set for at
least two periods. Part of the ventilation time should be scheduled during
the night, when people are sleeping. For instance, a fan could be scheduled
for 6 pm-12 midnight and 6 am-10 am for a household with nobody home during
the day, while a parent home with preschool children might want to ventilate
24 hours a day.
Controls are now available that perform several
functions. Honeywell has an integrated "comfort setter" that combines a
thermostat with a ventilation control, a humidity sensor, and an outdoor
thermometer. Called the PC8900, it allows the installer to program the
ventilation run time and "remembers" if the air handler ran in the last
half hour. American ALDES and Tamarack Technologies offer a combination
timer and speed control called the Airetrak. This device allows the use
of a larger fan that can be set to run at a lower and quieter speed for
general ventilation; it includes a push-button override to full speed for
20 minutes, and a programmable duty cycle for general ventilation. The
Airetrack was developed to be used with the new "condenser" motor in a
Panasonic fan; it is the only speed control that Panasonic allows to be
used with its fans.
These two-unit condominiums are part of the Winslow
Cohousing Project on Bainbridge Island, WA. The units use ventilating heat-pump
water heaters (also called heat-recovery water heaters) to provide both
ventilation and hot water. |
If the ventilation system is designed to operate
continuously to provide both spot ventilation and general ventilation,
no timer is needed. When the general ventilation fan is also used as an
intermittent spot fan, a switch or interval timer must be installed so
that people can turn the fan on when needed.
Additional ventilation time may be needed during
large parties or when someone is working on hobbies or other activities
that produce noxious odors or extra moisture.
Go Forth and Ventilate
The old adage to "build it tight and ventilate it
right" still holds true. The designer, the builder, and the occupant are
all best served by building the home relatively tight and then installing
and operating a mechanical ventilation system that is appropriate for the
house, the occupants' lifestyle, and the climate.
Resources
The Certified Home Ventilating Products Directory,
The
Home Ventilating Institute (HVI), 30 West University Dr., Arlington Heights,
IL 60004-1893. Tel:(708)394-0150.
ASHRAE 62-Ventilation for Acceptable Indoor
Air Quality, ASHRAE, 1791 Tullie Circle NE, Atlanta, GA, 30329-2305.
Tel:(404)636-8400; Fax:(404)321-5478.
Understanding Ventilation: How to Design,
Select, and Install Residential Ventilation Systems, by John Bower,
The Healthy House Institute, 430 N. Sewell Rd., Bloomington, IN 47408.
Oikos/Green Construction Source (Features
REDI 96, an online directory of products, including ventilation fans, devices,
and controls.) Iris Communications, P.O. Box 5920, Eugene, OR, 97405-0911,
Tel:(541)484-9353, World Wide Web address: http://irisinc.com/oikos
AIRBASE (database of over 7,000 abstracts
of international papers on infiltration and ventilation), Air Infiltration
and Ventilation Centre, Sovereign Court, University of Warwick Science
Park, Sir William Lyons Road, Coventry, CV4 7EZ, U.K. Tel:44-203-692050,
Fax:44-203-416306.
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