OPERATION AND
INSTALLATION MANUAL
NOTE: ALTHOUGH SOME MODELS
For Models:
DIFFER IN OPERATION, THE BASIC
STEPS ARE SIMILAR.
700DDPOOL
CAUTION
1200DDPOOL
1000RHC
1000RHCAC
Before installation, careful consideration must be
given to how the system will operate if connected to
any other piece of mechanical equipment, i.e. a forced
air furnace or air handler, operating at a higher static.
After installation, the compatibility of the two pieces of
equipment must be confirmed, by measuring the
airflow’s of the Heat/Energy Recovery Ventilator
(HRV), by using the balancing procedure in
this manual.
It is always important to assess how the operation
of any HRV may interact with vented combustion
equipment (ie. Gas Furnaces, Oil Furnaces, Wood
Stoves, etc.).
NEVER install an HRV in a situation where its normal
operation, lack of operation or partial failure may result
in the backdrafting or improper functioning of vented
combustion equipment!!!
TO BE COMPLETED BY CONTRACTOR AFTER INSTALLATION
Installing Contractor
Telephone / Contact
Serial Number
Installation Date
Model
* LEAVE FOR HOMEOWNER
NOTE: Due to ongoing research and product development, specifications,
ratings and dimensions are subject to change without notice.
TI-81C
1203
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Model 700DD POOL
SPECIFICATIONS
PERFORMANCE
AIRFLOWS (Each Air Stream)
CORES
Modular (2 section) patented aluminum heat recovery cores arranged
for efficient cross-flow ventilation.Meets the flame spread and smoke
developed classifications of the National Building Code and NFPA 90A
(1993 Edition)
423 (900)
378 (800)
329 (700)
282 (600)
235 (500)
190 (400)
143 (300)
94 (200)
5.5 HIGH
MOTORS
HIGH SPEED
5.0 MED
Two PSC, 3 speed single shafted, 120 VAC, 2.75 Amps each (5.5 total on
high speed). HP - 1/10, 1625 RPM. Watts - total on high speed - 648.
MED SPEED
4.7 LOW
LOW SPEED
FILTERS
Washable air filters in exhaust and supply air streams.
BLOWERS
42 (100)
Centrifugal type rated at 700 cfm (329 L/s) free air delivery. Each air
stream has one single shafted motor driving a centrifugal blower.
25 (.1) 50 (.2) 75 (.3) 100 (.4) 125 (.5) 150 (.6) 175 (.7)
EXTERNAL STATIC PRESSURE IN PASCALS (IN. W.C.)
CONNECTION DUCT SIZES
Five - 14" x 8" H (356 mm x 200 mm H).
TEMPERATURE EFFECTIVENESS
MOUNTING
Unit to be set on support brackets hung by threaded rod type
apparatus. (brackets and rod not provided.)
70%
60%
50%
CASE
20 gauge prepainted galvanized steel (G60) for superior corrosion
resistance. Insulated with foil faced insulation duct liner where required to
prevent exterior condensation. Drain connections; two - 1/2" (12 mm)
O.D.
CONTROLS
NOTE: Exhaust Relative Humidity (RH) at 40%
Illuminated power switch, 3 speed blower control, low voltage (24 VAC)
terminals for connection of remote dehumidistat (supplied) and defrost
light indicating automatic operation.
190
329
143
(300)
235
282
(400)
(700)
(500)
(600)
AIRFLOW IN L/s (CFM)
DEFROST
Supply bypass routes indoor air to defrost core.
WEIGHT 142 lbs. (64.4 kg) SHIPPING WEIGHT 167 lbs. (75.8 kg)
DIMENSIONS 700DDPOOL mm (inches)
SUPPLY AIR
FROM OUTSIDE
MOUNTING POINTS
CONTROLS
EXHAUST AIR
TO OUTSIDE
POOL AND
DEFROST
AIR
356 mm
(14")
356 mm
(14")
165 mm
(6 1/2")
165 mm
(6 1/2")
NOTE:
Service clearance
is 760 mm (30 in.)
from front
625 mm
(24 5/8 ")
210 mm
(8 1/4")
159 mm
(6 1/4")
access doors
200 mm
(8")
200 mm
(8")
SUPPLY AIR
TO BUILDING
EXHAUST AIR
FROM POOL
730 mm
(28 3/4")
730 mm
(28 3/4")
DRAIN CONNECTION
753 mm (29 5/8")
FRONT VIEW
All units conform to CSA and UL standards.
DISCHARGE SIDE
INLET SIDE
WARRANTY
All units carry a 15 year warranty on the heat recovery cores
and a 2 year replacement parts warranty.
DATE: ____________________________________________PROJECT: _______________________________________
MECHANICAL CONTRACTOR: _________________________________________________________________________
TI-104
1203
3
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Model 1200DD POOL
SPECIFICATIONS
CORES
PERFORMANCE
Modular (3 section) patented aluminum heat recovery cores arranged
for efficient cross-flow ventilation. Meets the flame spread and smoke
developed classifications of the National Building Code and NFPA 90A
(1993 Edition).
AIRFLOWS (Each Air Stream)
613 (1300)
566 (1200)
518 (1100)
472 (1000)
423 (900)
378 (800)
329 (700)
282 (600)
235 (500)
8.1 HIGH
MOTORS
7.8 MED
Two PSC, 3 speed double shafted, 120 VAC, 4 Amps each (8.1 total
on high speed). HP - 1/4, 1625 RPM. Watts - total on high speed -
972.
HIGH SPEED
7.1 LOW
MED SPEED
FILTERS
Washable air filters in exhaust and supply air streams.
LOW SPEED
BLOWERS
Centrifugal type rated at 1200 cfm (566 L/s) free air delivery. Each air
stream has one double shafted motor driving a centrifugal blower.
25 (.1) 50 (.2) 75 (.3) 100 (.4) 125 (.5) 150 (.6) 175 (.7)
EXTERNAL STATIC PRESSURE IN PASCALS (in. W.C.)
CONNECTION DUCT SIZES
Five - 20" x 8" H (508 mm x 200 mm H).
TEMPERATURE EFFECTIVENESS
MOUNTING
Unit to be set on support brackets hung by threaded rod type
apparatus. (brackets and rods not provided).
70%
60%
50%
CASE
20 gauge prepainted galvanized steel (G60) for superior corrosion
resistance. Insulated with foil faced insulation duct liner where required
to prevent exterior condensation. Drain connections; two - 1/2" (12
mm) O.D.
CONTROLS
NOTE: Exhaust Relative Humidity (RH) at 40%
Illuminated power switch, 3 speed blower control, low voltage (24 VAC)
terminals for connection of remote dehumidistat (supplied) and defrost
light indicating automatic operation.
235
282
329
378
423
472
518
566
(500)
(600)
(700)
(800)
(900)
(1000)
(1100)
(1200)
DEFROST CONTROLS
AIRFLOW IN L/s (CFM)
Supply bypass damper routes indoor air to defrost core.
WEIGHT 191 lbs. (87 kg) SHIPPING WEIGHT 215 lbs. (98 kg)
DIMENSIONS 1200DDPOOL mm (inches)
SUPPLY AIR
FROM OUTSIDE
MOUNTING POINTS
EXHAUST AIR
TO OUTSIDE
CONTROLS
POOL AND
DEFROST AIR
508 mm
(20")
508 mm
(20")
263 mm
(10 3/8")
263 mm
(10 3/8")
NOTE:
Service clearance
is 760 mm (30 in.)
from front
625 mm
(24 5/8 ")
172 mm
(6 3/4")
159 mm
(5 7/8")
access doors
200 mm
(8")
200 mm
(8")
EXHAUST AIR
FROM POOL
1055 mm
(41 1/2")
1055 mm
(41 1/2")
DRAIN CONNECTION
759 mm (29 7/8")
SUPPLY AIR
TO BUILDING
FRONT VIEW
DISCHARGE SIDE
INLET SIDE
All units conform to CSA and UL standards.
WARRANTY
Units carry a 15 year warranty on the heat recovery cores
and a 2 year replacement parts warranty.
DATE: ___________________________________________PROJECT: _________________________________________
MECHANICAL CONTRACTOR: _________________________________________________________________________
TI -121
1203
4
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Model 1000RHC and
Model 1000RHCAC
SPECIFICATIONS
CORES
PERFORMANCE
Modular (3 section) patented aluminum heat recovery cores arranged for
high efficiency cross-flow ventilation. Meets the flame spread and smoke
developed classifications of the National Building Code and NFPA 90A (1993
Edition).
AIRFLOWS (Each Air Stream)
613 (1300)
566 (1200)
518 (1100)
472 (1000)
423 (900)
378 (800)
329 (700)
282 (600)
235 (500)
8.1 HIGH
MOTORS
Two PSC, 3 speed double shafted, 120 VAC, 3.95 Amps each (7.9 total on
high speed). HP - 1/4, 1625 RPM. Watts - total on high speed - 848.
7.8 MED
HIGH SPEED
FILTERS Washable air filters in exhaust and supply air streams.
7.1 LOW
BLOWERS
Each air stream has one double shafted motor driving 2 centrifugal blowers.
HYDRONIC REHEAT COIL
Standard built-in coil in both 1000RHC and 1000RHCAC. Rated 35,000 BTU
@ 140°F, 3 US gal./min. Design temperature drop is 20°F, fluid pressure drop
is 1.3 feet WG at rated flow, 3/4" fittings.
25 (.1) 50 (.2) 75 (.3) 100 (.4) 125 (.5) 150 (.6) 175 (.7) 200 (.8)
EXTERNAL STATIC PRESSURE IN PASCALS (in. W.C.)
CONNECTION DUCT SIZES Five - 20" X 8" H (508 mm x 200 mm H).
TEMPERATURE EFFECTIVENESS
DIRECT EXPANSION (DX) EVAPORATOR COIL (model 1000RHCAC
only) Factory installed 1.5 ton DX coil, 0.875" OD suction side, 0.625" OD
liquid side, built-in orifice.
MOUNTING
70%
60%
50%
Two brackets under cabinet, connect to threaded rod type supports
(not included).
CASE
20 gauge prepainted galvanized steel (G60) for superior corrosion resistance.
Insulated with foil faced insulation where required to prevent exterior conden-
sation. Drain connections; two - 1/2" (12 mm) O.D.
CONTROLS
NOTE: Exhaust Relative Humidity (RH) at 40%
Illuminated power switch, 3 speed blower control, low voltage (24 VAC) termi-
nals to connect remote controls (not included), defrost light indicating
defrost/recirculation mode.
235
282
329
378
423
472
518
566
(500)
(600)
(700)
(800)
(900)
(1000)
(1100)
(1200)
AIRFLOW IN L/s (CFM)
DEFROST CONTROLS
Supply bypass damper routes indoor air to defrost core.
Performance data includes both reheat and DX coil installed.
Note there is little change in air flow with the DX coil removed.
WEIGHT 255 lbs.(116 Kg)
SHIPPING WEIGHT 280 lbs.(127 Kg)
mm (inches)
DIMENSIONS 1000RHC/RHCAC
SUPPLY AIR
FROM OUTSIDE
DEFROST &
RECIRCULATION
AIR
EXHAUST AIR
TO OUTSIDE
CONTROLS
263 mm
508 mm
(20 ")
508 mm
(20")
(
10 3/8 ")
NOTE:
Service clearance
is 760 mm (30 in.)
149 mm
625 mm
(24 5/8")
(
5 7/8 ")
263 mm
(10 3/8 ")
508 mm
(20 ")
200 mm
(8")
EXHAUST AIR
FROM BUILDING
1088 mm
(46 3/4")
1055 mm
(41 1/2")
DRAIN CONNECTION
COIL FITTINGS
SUPPLY AIR
TO BUILDING
DISCHARGE SIDE
INLET SIDE
FRONT VIEW
99-101 Sixty Minute Remote Timer
WARRANTY
Units carry a 15 year warranty on the heat recovery cores and
a 2 year replacement parts warranty.
99-130 Remote Wall Mount Dehumidistat Control
24VAC only
All units conform to CSA and UL standards.
NOTE: Hydronic reheat coil is designed to temper the ventilation air (after heat recovery) back to room temperature, and is not
intended for use as a primary heating source for the space.
•
•
Additional controls MUST be added to pump system (not included / not available from Nutech) feeding the coil to ensure
continuous water flow through it, and prevent freezing of the coil.
DX coil is designed to reduce humidity brought in from outside during ventilation. Coil MUST be connected to an outdoor
condensing unit (not included) by certified trades person. Not intended as a primary air conditioning system for the space.
DATE:_____________________________________________PROJECT: ________________________________________
MECHANICAL CONTRACTOR: __________________________________________________________________________
TI-115
5
1203
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Sizing your Pool Heat Recovery Ventilator
Determining ventilation requirements for
Indoor Pool enclosures
Moisture removal capabilities
In addition to the amount of air being exchanged,
moisture removal depends largely on the moisture
content of both the inside and outside air. The
trends below outline these principles.
There are two primary reasons to ventilate an indoor
pool enclosure. One is to provide effective and
efficient control of harmful humidity levels. The other
reason is to control the Indoor Air Quality (IAQ) in
the pool room enclosure. When an HRV system is
adequately sized to control humidity,
the IAQ will automatically be controlled for most
situations. Therefore this HRV sizing guide will focus
on the amount of moisture introduced into
the air from the pool and the moisture removing
capabilities of an HRV at various flow rates.
• The higher the indoor relative humidity, the
larger the moisture removing capabilities.
• The higher the indoor temperature, the larger
the moisture removing capabilities
• The lower the outdoor temperature, the
larger the moisture removing capabilities.
Detailed Calculation of Total
Ventilation Requirements
The amount of moisture evaporated
from a pool is effected by:
The following charts and equations can be used
to accurately size the HRV for a indoor pool
application. At this time some decisions should be
made with regards to:
1. Surface area of the pool
2. The water temperature
3. Indoor air temperature
4. Indoor relative humidity (R.H.)
5. The amount of activity in the pool room
• Pool water temperature
• Indoor air temperature
• Relative humidity
These short rules will help in understanding
how these factors will effect moisture
generation
It should be noted that the construction and quality of
materials used in the construction of the pool room will
influence the size of HRV required. High quality
windows such as triple glazed, argon filled will allow a
higher indoor humidity level before condensation will
occur. A pool room built with loose construction
techniques will have a higher natural ventilation rate
than that of a room built to higher standards. It is
recommended for all applications it is assumed there is
no natural ventilation.
1. Larger areas of water will evaporate greater
amounts of water.
(By using a pool cover the surface area of the
pool will be reduced and will substantially reduce
water evaporation.)
2. Higher water temperatures will increase water
evaporation.
The first table contains the evaporation rate of
water based on the water temperature, room
temperature, and room relative humidity.
3. Lower indoor air temperatures will increase water
evaporation.
4. Lower indoor relative humidity will increase water
evaporation.
The second table contains the flowrate factor
based on the indoor temperature, outdoor
temperature, and room relative humidity.
5. Activities in the pool will increase the water
surface area, therefore water evaporation will
increase.
The total ventilation rate per square foot of water
surface area is the result of these calculations. The
total ventilation rate is this product multiplied by the
water surface area.
6
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Calculation
Note:
As a general rule, if the water temperature is maintained at 80˚F and the pool room air
temperature is maintained at 82˚F, use a factor of 1 cfm/sq ft of pool surface or .5 cfm/sq ft of room
area (whichever is greater) to determine amount of ventilation required.
Example:
Pool surface area
16’ x 32’ (512 sq ft)
83 ˚F
*Indoor design air temperature
Pool water temperature
Relative Humidity
81 ˚F
50 %
15 ˚F
*Outdoor design air temperature
* Always use design temperatures for indoor and outdoor air temperatures. Outdoor design temperatures
are published by organizations such as ASHRAE. Do not us day to day temperatures for this calculation.
1. From Table 1, select the appropriate evaporation rate based on the room air temperature,
water temperature, and relative humidity.
Evaporation Rate = 0.052
2. From Table 2, select the corresponding flowrate factor depending on the indoor air temperature,
outdoor temperature, and room relative humidity.
Flowrate Factor = 21.70
3. Multiply the values obtained from step 1 and step 2 to obtain the minimum CFM
required per square foot of pool surface area.
Evaporation rate
0.052
X
X
Flowrate
21.70
= CFM / square foot of water surface area
= 1.12
4. Multiply the value in step 3 by the area of the pool
Area of pool
512
X
X
Value for step 3
1.12
= CFM
573
=
System Installation
It is necessary to design and size the duct distribution system for both the supply and the exhaust
air streams.
Proper duct design will
• Minimize air flow requirements
• Ensure a comfortable environment by using reheat if required
• Optimize humidity control, including eliminating condensation on windows by
blanketing the windows with airflow
Please refer to sketch 1 and 2 for typical duct layouts.
7
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Evaporation Rate
Indoor Relative Humidity
TABLE 1
40%ꢀ 50%ꢀ 60% 40%ꢀ 50%ꢀ 60% 40%ꢀ 50%ꢀ 60% 40%ꢀ 50%ꢀ 60% 40%ꢀ 50%ꢀ 60% 40%ꢀ 50%ꢀ 60%
Evaporation Rate lb/(sq. ft-hr.)
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
68ꢀ 0.069ꢀ 0.063ꢀ 0.056ꢀ 0.079ꢀ 0.073ꢀ 0.066ꢀ 0.090ꢀ 0.084ꢀ 0.077ꢀ 0.102ꢀ 0.095ꢀ 0.089ꢀ 0.115ꢀ 0.108 0.102 0.129 0.122 0.116
70ꢀ 0.068ꢀ 0.060ꢀ 0.053ꢀ 0.078ꢀ 0.070ꢀ 0.063ꢀ 0.088ꢀ 0.081ꢀ 0.074ꢀ 0.100ꢀ 0.093ꢀ 0.086ꢀ 0.113ꢀ 0.106ꢀ 0.099 0.127 0.120 0.113
72ꢀ 0.065ꢀ 0.058ꢀ 0.050ꢀ 0.075ꢀ 0.068ꢀ 0.060ꢀ 0.086ꢀ 0.079ꢀ 0.071ꢀ 0.098ꢀ 0.090ꢀ 0.083ꢀ 0.111ꢀ 0.103ꢀ 0.096 0.125 0.117 0.110
74ꢀ 0.063ꢀ 0.055ꢀ 0.047ꢀ 0.073ꢀ 0.065ꢀ 0.057ꢀ 0.084ꢀ 0.076ꢀ 0.068ꢀ 0.096ꢀ 0.088ꢀ 0.079ꢀ 0.109ꢀ 0.101ꢀ 0.092 0.123 0.115 0.106
76ꢀ 0.061ꢀ 0.052ꢀ 0.043ꢀ 0.071ꢀ 0.062ꢀ 0.053ꢀ 0.082ꢀ 0.073ꢀ 0.064ꢀ 0.094ꢀ 0.085ꢀ 0.076ꢀ 0.107ꢀ 0.098ꢀ 0.089 0.121 0.112 0.103
78ꢀ 0.059ꢀ 0.049ꢀ 0.039ꢀ 0.069ꢀ 0.059ꢀ 0.049ꢀ 0.080ꢀ 0.070ꢀ 0.060ꢀ 0.091ꢀ 0.082ꢀ 0.072ꢀ 0.104ꢀ 0.095ꢀ 0.085 0.118 0.109 0.099
80ꢀ 0.056ꢀ 0.046ꢀ 0.035ꢀ 0.066ꢀ 0.056ꢀ 0.045ꢀ 0.077ꢀ 0.067ꢀ 0.056ꢀ 0.089ꢀ 0.079ꢀ 0.068ꢀ 0.102ꢀ 0.091ꢀ 0.081 0.116 0.105 0.095
82ꢀ 0.053ꢀ 0.042ꢀ 0.031ꢀ 0.063ꢀ 0.052ꢀ 0.041ꢀ 0.074ꢀ 0.063ꢀ 0.052ꢀ 0.086ꢀ 0.075ꢀ 0.064ꢀ 0.099ꢀ 0.088ꢀ 0.077 0.113 0.102 0.091
84ꢀ 0.050ꢀ 0.039ꢀ 0.027ꢀ 0.060ꢀ 0.049ꢀ 0.037ꢀ 0.071ꢀ 0.060ꢀ 0.048ꢀ 0.083ꢀ 0.071ꢀ 0.060ꢀ 0.096ꢀ 0.084ꢀ 0.073 0.110 0.098 0.087
86ꢀ 0.047ꢀ 0.035ꢀ 0.022ꢀ 0.057ꢀ 0.045ꢀ 0.032ꢀ 0.068ꢀ 0.056ꢀ 0.043ꢀ 0.080ꢀ 0.068ꢀ 0.055ꢀ 0.093ꢀ 0.080ꢀ 0.068 0.107 0.094 0.082
88ꢀ 0.044ꢀ 0.031ꢀ 0.017ꢀ 0.054ꢀ 0.041ꢀ 0.027ꢀ 0.065ꢀ 0.052ꢀ 0.038ꢀ 0.077ꢀ 0.063ꢀ 0.050ꢀ 0.090ꢀ 0.076ꢀ 0.063 0.104 0.090 0.077
ꢀꢀꢀ
78ꢀꢀꢀ
81ꢀꢀꢀ
84ꢀꢀꢀ
87ꢀꢀꢀ
90ꢀ ꢀ
93
8
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TABLE 2
Flowrate Factor
Indoor Relative Humidity
40%ꢀ 50%ꢀ 60% 40%ꢀ 50%ꢀ 60% 40%ꢀ 50%ꢀ 60% 40%ꢀ 50%ꢀ 60% 40%ꢀ 50%ꢀ 60% 40%ꢀ 50%ꢀ 60%
Flowrate Factor (cfa-hr./lb.)
ꢀ
ꢀ
ꢀ
ꢀ
-30ꢀ 39.70ꢀ 31.50ꢀ 26.10ꢀ 35.70ꢀ 28.30ꢀ 23.40ꢀ 32.10ꢀ 25.50ꢀ 21.10ꢀ 29.00ꢀ 23.00ꢀ 19.00ꢀ 26.10ꢀ 20.70 17.20 23.60 18.70 15.50
-25ꢀ 40.20ꢀ 31.80ꢀ 26.20ꢀ 36.10ꢀ 28.50ꢀ 23.60ꢀ 32.40ꢀ 25.70ꢀ 21.20ꢀ 29.20ꢀ 23.10ꢀ 19.10ꢀ 26.30ꢀ 20.90ꢀ 17.20 23.80 18.80 15.60
-20ꢀ 40.80ꢀ 32.10ꢀ 26.50ꢀ 36.50ꢀ 28.80ꢀ 23.80ꢀ 32.80ꢀ 25.90ꢀ 21.40ꢀ 29.50ꢀ 23.30ꢀ 19.20ꢀ 26.60ꢀ 21.00ꢀ 17.40 24.00 19.00 15.70
-15ꢀ 41.60ꢀ 32.60ꢀ 26.80ꢀ 37.20ꢀ 29.20ꢀ 24.00ꢀ 33.30ꢀ 26.20ꢀ 21.60ꢀ 29.90ꢀ 23.60ꢀ 19.40ꢀ 26.90ꢀ 21.20ꢀ 17.50 24.20 19.10 15.80ꢀ
ꢀ -10ꢀ 42.60ꢀ 33.20ꢀ 27.20ꢀ 38.00ꢀ 29.70ꢀ 24.40ꢀ 34.00ꢀ 26.60ꢀ 21.90ꢀ 30.40ꢀ 23.90ꢀ 19.60ꢀ 27.30ꢀ 21.50ꢀ 17.70 24.60 19.30 15.90
ꢀ
-5ꢀ
43.90ꢀ 34.10ꢀ 27.80ꢀ 39.00ꢀ 30.40ꢀ 24.80ꢀ 34.80ꢀ 27.10ꢀ 22.20ꢀ 31.10ꢀ 24.30ꢀ 19.90ꢀ 27.90ꢀ 21.80ꢀ 17.90 25.00 19.60 16.10ꢀ
45.70ꢀ 35.10ꢀ 28.50ꢀ 40.40ꢀ 31.20ꢀ 25.40ꢀ 35.90ꢀ 27.80ꢀ 22.70ꢀ 32.00ꢀ 24.80ꢀ 20.30ꢀ 28.60ꢀ 22.20ꢀ 18.20 25.60 20.00 16.30
48.10ꢀ 36.50ꢀ 29.40ꢀ 42.30ꢀ 32.30ꢀ 26.10ꢀ 37.40ꢀ 28.70ꢀ 23.20ꢀ 33.20ꢀ 25.50ꢀ 20.70ꢀ 29.50ꢀ 22.80ꢀ 18.60 26.30 20.40 16.60
51.50ꢀ 38.40ꢀ 30.60ꢀ 44.90ꢀ 33.80ꢀ 27.00ꢀ 39.40ꢀ 29.80ꢀ 24.00ꢀ 34.70ꢀ 26.40ꢀ 21.30ꢀ 30.70ꢀ 23.50ꢀ 19.00 27.30 21.00 17.00
56.20ꢀ 41.00ꢀ 32.20ꢀ 48.50ꢀ 35.80ꢀ 28.30ꢀ 42.10ꢀ 31.40ꢀ 25.00ꢀ 36.80ꢀ 27.60ꢀ 22.10ꢀ 32.40ꢀ 24.50ꢀ 19.60 28.60 21.70 17.50
63.40ꢀ 44.70ꢀ 34.50ꢀ 53.70ꢀ 38.50ꢀ 30.00ꢀ 46.00ꢀ 33.50ꢀ 26.30ꢀ 39.70ꢀ 29.30ꢀ 23.10ꢀ 34.60ꢀ 25.70ꢀ 20.40 30.30 22.70 19.10
74.90ꢀ 50.10ꢀ 37.60ꢀ 61.70ꢀ 42.50ꢀ 32.40ꢀ 51.80ꢀ 36.40ꢀ 28.10ꢀ 44.00ꢀ 31.50ꢀ 24.50ꢀ 37.80ꢀ 27.40ꢀ 21.50 32.70 24.10 19.00
95.90ꢀ 58.70ꢀ 42.30ꢀ 75.30ꢀ 48.50ꢀ 35.80ꢀ 61.00ꢀ 40.80ꢀ 30.60ꢀ 50.50ꢀ 34.70ꢀ 26.40ꢀ 42.50ꢀ 29.80ꢀ 23.00 36.20 25.90 20.10
112.78ꢀ 69.62ꢀ 46.60ꢀ 84.08ꢀ 54.75ꢀ 38.60ꢀ 66.18ꢀ 44.71ꢀ 32.53ꢀ 57.46ꢀ 37.32ꢀ 27.77ꢀ 46.85ꢀ 31.63ꢀ 23.99 39.10 27.20 20.83
129.66ꢀ 80.53ꢀ 50.90ꢀ 92.86ꢀ 61.0ꢀ 41.40ꢀ 71.36ꢀ 48.63ꢀ 34.46ꢀ 64.43ꢀ 39.94ꢀ 29.13ꢀ 51.20ꢀ 33.47ꢀ 24.97 42.0 28.50 21.57
146.54ꢀ 91.45ꢀ 55.20ꢀ 101.64ꢀ 67.25ꢀ 44.20ꢀ 76.54ꢀ 52.55ꢀ 36.40ꢀ 71.39ꢀ 42.56ꢀ 30.50ꢀ 55.55ꢀ 35.30ꢀ 25.95 44.90 29.80 22.30
ꢀ 0ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
5ꢀ
10ꢀ
15ꢀ
20ꢀ
25ꢀ
30ꢀ
35ꢀ
40ꢀ
45ꢀ
50ꢀ
163.42
180.30
243.30
ꢀ
ꢀ
ꢀ
102.37ꢀ 59.50ꢀ 110.42ꢀ 73.50ꢀ 47.0ꢀ 81.72ꢀ 56.47ꢀ 38.30ꢀ 78.36ꢀ 45.18ꢀ 31.87ꢀ 59.90ꢀ 37.13ꢀ 26.93 47.80 31.10 23.03ꢀ
113.28ꢀ 63.80ꢀ 119.20ꢀ 79.75ꢀ 49.80ꢀ 86.90ꢀ 60.38ꢀ 40.26ꢀ 85.33ꢀ 47.80ꢀ 33.23ꢀ 64.25ꢀ 39.96ꢀ 27.92 50.70 32.40 23.76
124.20ꢀ 68.10ꢀ 127.98ꢀ 86.0ꢀ 52.60ꢀ 92.08ꢀ 64.30ꢀ 42.20ꢀ 92.30ꢀ 50.40ꢀ 34.60ꢀ 68.60ꢀ 40.80ꢀ 28.90 53.60 33.70 24.50
55ꢀ
ꢀ
60ꢀ
ꢀꢀꢀ
68ꢀꢀꢀ
71ꢀꢀꢀ
74ꢀꢀꢀ
77ꢀꢀꢀ
80ꢀꢀ
83ꢀ
9
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Installation Diagrams
EXPOSED WALL
Blanket exposed
windows with
fresh dry air
Main
Stale Air
Intake
EXPOSED WALL
HRV
Min. 10’-0"
Always attempt to minimize
short circuiting of air streams,
(supply fresh air on one side
of room and exhaust stale air
from opposite side of room).
Typical Duct Layout
Sketch #1
10
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EXPOSED WALL
Blanket exposed
windows with
fresh dry air
Stale Air
Intake
EXPOSED WALL
HRV
Min. 10’-0"
Always attempt to minimize
short circuiting of air streams,
(supply fresh air on one side
of room and exhaust stale air
from opposite side of room).
Typical Duct Layout
Sketch #2
11
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Location for Mounting
The Ductwork System
The HRV must be located in a heated space
where the surrounding air temperature does not
fall below 60˚F (16˚C). The unit must be mounted
level (horizontal) to obtain proper drainage or
water from the heat exchange element and drip
pans. The warranty will be void if these
conditions are not met.
A properly designed ducting system will allow the
HRV to operate at its maximum efficiency. (Air
flow will be restricted by undersized ducting, use
of too many elbows, tees, bends, etc.). Always
try to keep duct runs as short and straight as
possible.
NOTE: Fully insulated ducting with an integral
vapour barrier must be used on all runs
passing through unheated areas in order
to avoid condensation problems and
energy losses from the air steams.
Typically, the HRV is positioned close to an
outside wall or the roof to simplify the
connections and keep the length of insulated
ducting required for the fresh air intake to a
minimum.
All joints must be airtight, sealed and impervious
to moisture. See specification sheets for each
unit for exact duct sizes and location.
A minimum clearance of 30 inches (76 cm) in
front of the HRV is recommended to service the
heat exchanger cores and the filters. The HRV
may be mounted on an equipment platform
providing the drain hoses are clear and there is
sufficient space to open the doors for servicing.
To minimize pressure drop and noise, galvanized
metal ducts, properly sized, are recommended.
Keep ducting as short as possible and use a
minimum of elbows and tees. Connecting sections
and shorter runs may be flexible ducting one size
larger than the metal equivalent. Use flexible duct
connectors at the HRV to avoid noise transmis-
sion.
Install the drain pans in the bottom of the HRV
so the drain connections protrude through the
holes provided. Use drain hoses with hose
clamps to connect the drain pan outlets to a floor
drain or standpipe. Make sure the drain line
slopes down to the outlet. If this is not possible a
condensate pump will be required for positive
removal of the water. Protect the drain line from
freezing.
All duct joints must be secured with screws,
rivets or duct sealant and sealed with aluminum
duct tape to prevent leakage.
HRV CABINET
DRAIN
SPOUT
DRAIN
SPOUT
TAPE
TEE
CONNECTOR
TO DRAIN
Forming the “P” Trap
12
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Outside Weatherhoods
Stale Air Return System
The weatherhoods must have built-in “bird” screen with
1/4 in (6.35 mm) minimum mesh to prevent birds and
rodents from entering into the ductwork. Do not use
smaller mesh as it will be very susceptible to plugging
up. Gravity dampers at the vents must not be used as
they will restrict air flow and often “seize up”. The pre-
ferred location of the outside weatherhoods is:
The stale air return system is used to draw air from the
points in the building where the worst air quality prob-
lems occur. Balancing dampers and/or adjustable
grilles are recommended on all return air lines which
are used during installation to help balance the “draw”
from different areas of the building.
Alternately, the stale air may be drawn directly from the
return air duct. When this system is used, the air han-
dler’s blower must constantly operate. The exhaust
takeoff connection must be at least a 3 ft (1 m) from a
directly connected HRV supply duct if both are con-
nected to the same duct run. Static pressure of the air
handlers return system should be noted and compen-
sated for if, it is apparent that the static pressure of the
return in the air handler will exceed .1 to .15” W.C.
• no less than 10 ft. (3 m) apart from each other
• at least 18 in ( 46 cm) above snow line or
ground level
• away from sources of contaminants, such as
automobile exhaust fumes, gas meters, garbage
cans, containers, etc.
• not exposed to prevailing winds, whenever
reasonable possible
A damper located just prior to the HRV is required to
balance the stale air exhausted with the fresh air sup-
ply entering the building.
The outside perimeter of the weatherhood must be
caulked to prevent leakage into the building.
The design and size of the weatherhoods or louvres
chosen by the installer must allow for adequate free
area. Water and snow penetration of the system is mini-
mized when the airflow does not exceed 1000 FPM
(5.08 m/s) free area velocity.
Return air suction points should be located on the
opposite side of the room from the fresh air inlet. The
inlets may be located in the ceiling or high on the walls
and fitted with inlet grilles.
Many commercial activities produce air contaminants in
the form of dusts, fumes, mists, vapours and gases.
Contaminants should be controlled at the source so that
they are not dispersed through the building nor allowed
to increase to toxic concentration levels. The ventilator
allows for economical operation of the HVAC system
while effectively removing contaminants from the space.
Ducting from the
Weatherhoods
Galvanized sheet metal ducting with sufficient cross sec-
tion with an integral single piece vapour barrier should be
used to connect the HRV to the weatherhoods. All duct-
ing must meet UL Class 1 requirements.
In designing the exhaust portion of the system the
exhaust grilles are placed so as to remove the contami-
nants while not allowing them to enter the breathing
zone of the occupants.
A minimum R value of insulation should be equal to 4
(RSI 0.75)
A good bead of high quality caulking (preferably acousti-
cal sealant) and taping with a high quality aluminum foil
tape is recommended to seal the duct to both the HRV
and the weatherhood.
For contaminants that are lighter than air, grilles should
be located high on the wall. If contaminants are heavier
than air, a lower placement of the grilles will be
required. Information on a contaminants specific gravity
and toxicity should be available from chemical data
sheets.
Warmside Ducting - General
Ducting from the HRV to the different areas in the build-
ing should be galvanized metal whenever possible.
To minimize airflow losses in the ductwork system, all
ducts should be as short as possible and with as few-
bends or elbows as possible. 45° elbows are preferred
to 90° elbows. Use “Wye” (Y) fittings instead of “Tees”
(T) whenever possible.
All duct joints must be fastened with screws, rivets or
duct sealant and wrapped with a quality duct tape to pre-
vent leakage. We recommend aluminum foil tape.
13
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Fresh Air Supply System
The fresh air supply ductwork from the HRV may be
directly connected to the return air duct of the forced
air system. Check the air flow balance of the HRV with
the air handler blower both “ON” and “OFF” to
determine that it does not imbalance the HRV more
than 10%. Also, it is advisable to include a short length
of flex duct or other non-metallic connector in this hard
ducted line in order to keep the HRV acoustically iso-
lated and separately grounded (electrically) from the
air handler. This will avoid a possible shock hazard to
service people if a short to ground develops in one of
the devices.
Supply air grilles may be ceiling or high wall mounted.
Avoid locating incoming fresh air grilles that could
cause a direct draft on the occupants as the incoming
air may be below room temperature. A reheat duct
heater can be installed to improve occupant comfort.
The use of balancing dampers or adjustable grilles to
balance the flow rates into various rooms is
recommended.
The use of balancing dampers or adjustable grilles
as supply air diffusers and air exhaust covers are
recommended. TECHGRILLES™ are round, efficient,
sound absorbing devices available in 4”, 5”, 6” and 8”
(100, 125, 150, and 200 mm) models.
It may be necessary to install a separate fresh air supply
ductwork system if the heating is other than forced air.
When installing an HRV, the designer and installer
should be aware of local codes that may require
smoke detectors and/or firestats in the HVAC or HRV
ductwork.
Because an HRV is designed to bring fresh air into the
building, structures may require supply voltage
interrupt when smoke or flame sensors are triggered,
or when a central fore alarm system is activated.
AIR FLOW
SUPPLY
AIR FLOW
EXHAUST
TECHGRILLE
(optional) schematic
14
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Various Installation Types
NOTE: When installing your HRV
flexible duct connectors should
be installed between the HRV
and the galvanized duct work.
Figure 7A
Saddle Installation
Vibration Isolators
(Supplied by others)
Threaded
rod and U channel
(Supplied by others)
Hang unit with suspended rods
and "U" channel members.
Figure 7B
Curb Mounted
Curb is wood or metal
(Supplied by others)
May be anchored to
floor,leaving space
for drain connections
Mount unit on wooden or metal
curb assembly. Unit must be raised
an adequate height for installation
and slope of drain lines.
Figure 7C
Suspended
Vibration Isolators
(Supplied by others)
PVC Support Straps
(Supplied by others)
Unit Suspended using
Polyester reinforced PVC support straps.
15
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Electrical Connections
Automatic Self Test of Defrost
Systems
It is recommended that a licensed electrician make all
electrical connections. It is very important that the
unit be properly grounded. It is recommended that a
separate 15 amp/120 volt circuit be used.
If confirmation of the defrost system is needed,
complete the following steps.
1. Disconnect power to the unit and open access/
WARNING: In order to prevent electric shock when
cleaning or servicing the HRV, it is extremely important
to confirm the polarity of the power line that is switched
by the safety (disconnect) switch whose control arm is
located on the outside of the electrical control box area.
The hot line (black) is the proper line to be switched. To
confirm the proper polarity, use a voltmeter or test lamp
to make sure there is no power after the switch when
the door is open. Check between that point and ground
(on the cabinet). This must be done as occasionally
some buildings are improperly wired. Always make
sure the HRV is properly grounded.
maintenance doors.
2. Locate the “snap disc” type temperature sensor
mounted in the upper left hand corner (cold air
stream) of the HRV.
3. Disconnect the two wires from the HRV to the
sensor, at the sensor.
4. Using a jump wire with alligator clips, join two
wires from the HRV together.
5. Close access doors and power the unit.
This procedure will simulate a defrost that would occur
automatically in the field when the outside temperature
drops below -3˚C (27˚F).
Black
Power Supply
Line
White
Cord
Black
Neut.
Power
Terminal
Block.
GND.
Electrical Connection
DAMPER DEFROST
These damper defrost HRV’s have an electronically
controlled damper defrost mechanism. If the outside
temperature drops below 27˚F(-3˚C ), the defrost timer
is activated. A motor driven damper door mechanism
opens the defrost port and at the same time closes off
the supply air from outside. After approximately 3
minutes, the damper operates in the opposite direction
to close off the defrost port and reopen the fresh air at
the supply port. The 27.5 minute wait time and 3
minute defrost cycle repeat until the temperature again
rises above 27˚F (-3˚C).
16
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Operation of the HRV
These Recirculating Models of HRV's will provide fresh
clean air without sacrificing the savings of your energy
conserving home. When outdoor air is required for pool
room dehumidification, the aluminum cores of the HRV
provide effective and efficient heat recovery exchange.
Whether operating as an HRV or in recirculation mode,
the energy efficient PSC blower motors provide reliable
and cost effective operation.
The exhaust fan to the outside is shut off during this time.
Outside air does not enter the system until the pool room
humidity exceeds the setpoint of the dehumidistat.
The unit has an electronically controlled damper door
defrost. If the dehumidistat has made its circuit and the
unit is drawing in outside air, the defrost cycle will
operate as follows:
Operation:
If the outside temperature drops below 27˚ Fahrenheit
(-3 degrees Celsius) the defrost timer is activated. After
waiting approximately 27.5 minutes (during which time
the core unit may experience some frost build-up) the
timer activates the damper door mechanism which
closes off the fresh air supply port and opens the
defrost port. After approximately 3 minutes the damper
door reverses direction and re-opens the fresh air sup-
ply port and closes off the defrost port. This cycle
repeats until the outside temperature again rises
above 27˚ F.
Humidity control is provided by an adjustable dehumidistat
that is mounted in the pool room. The dehumidistat
(supplied and mounted in the pool room in an accessible
location 5' above floor level) would be set to a humidity
level the operator finds acceptable (for example, in a
range of 45 to 55% R.H.). If the humidity level in the
room exceeds the setting of the dehumidistat, then
outside air is brought into the system and humid air is
removed from the room. If a duct heater or hot water
coil has been installed in the supply ductwork, this will
condition the incoming air.
During the defrost cycle, pool room air is moved
outside through the unit as well as from the pool room,
back to the pool room. To handle the required air flow
capacity, two ducts need to be connected to the pool
room or one large duct.
Control of this heater would be by a duct mounted
thermostat. When the humidity level of the room falls
to the dehumidistat setpoint, the pool room air is
recirculated and no outside air will enter the system.
Pool room air moves through the unit, then to the duct
heater (optional) and returns to the pool room. Outside
air is prevented from entering the unit during recirculation
by the supply damper closing off.
17
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Ducting Requirements & Mode of Operation
Ventilation Mode
Defrost Mode
In ventilation mode, both motors are running and air is
being exchanged with the outside through the supply
and exhaust ducts.
In defrost mode both the supply and exhaust motors
run to draw air through the heat exchange cores. This
mode is automatic and does not require field
adjustments. Defrost light on side of cabinet illuminates
to indicate defrost operation.
Recirculation Mode
In recirculation mode the supply motor continues to run
and a damper moves to block off air entering from
outside, drawing air instead from the conditioned
space. The exhaust to outside motor is OFF when in
recirculation mode.
*NOTE: "Defrost" light is illuminated during
"Recirculation Mode", indicating damper direction.
1. VENTILATION MODE
FRESH AIR FROM OUTSIDE
EXHAUST TO OUTSIDE
FROM POOL ROOM (CLOSED)Ø
ON
ON
FROM POOL ROOM
TO POOL ROOM
2. RECIRCULATION MODE
FRESH AIR FROM OUTSIDE (CLOSED)
Ø
EXHAUST TO OUTSIDE
FROM POOL ROOM
FROM POOL ROOM
Ø
OFF
ON
Ø
TO POOL ROOM
3. DEFROST MODE
FRESH AIR FROM OUTSIDE (CLOSED)
Ø
EXHAUST TO OUTSIDE
FROM POOL ROOM
NOTE:
ON
ON
The external low voltage
contacts on a pool unit
control the Ventilation/
Recirculation Damper only,
not low/high speed control.
FROM POOL ROOM
TO POOL ROOM
18
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Speed Selection and Controls
Air Conditioning (DX) Coil
Model 1000RHCAC Only
These recirculation models are equipped with a
3 speed control, low medium and high, (Note -
1000RHC/RHCAC must be set to high speed
when air conditioning is required), as well as a
lighted on/off switch and a low voltage terminal
strip. The low voltage terminal strip is used to
connect the supplied dehumidistat.
The Direct Expansion (DX) Coil located inside the cabi-
net is designed to dehumidify the incoming fresh air
from the outside and is not intended as an air condition-
ing unit for the space. The coil must be connected to
an outdoor condensing unit, (this unit or it’s controls are
not provided by NUTECH). Special care and atten-
tion should be given to ensure the Model
1000RHCAC is set to high speed during air condi-
tioning mode, to avoid the coil from freezing up.
DEHUMIDISTAT
END OF UNIT
ON/OFF SWITCH
not used
3 SPEED CONTROL
t
e
io
ta
is
id
m
u
g
e
h
in
id
ts
e
tt
D
e
u
o
t
HIGH
v
ti
la
e
R
C
S
O
s
n
it
d
n
o
COMMON
:
R
TE
IN
W
idistat
to 40%
Set dehum
een 30%
.
betw
e
is too dry,
If hom
id,
adjust to higher setting.
e
is too hum
er setting.
If hom
adjust to low
:
ER
M
UM
S
idistat
Set dehum
FF.
to
O
* NOTE: The external low voltage contacts on a pool
unit control the Ventilation/Recirculation
PART NO. 99-130W
Damper only, not low/high speed control.
•Provides ventilation or recirculation mode
Hydronic Reheat Coil
DISCLAIMER
Model 1000RHC and 1000RHCAC
The Model 1000RHC and RHCAC is intended to
be installed by certified HVAC trades people.
Damage resulting in partial or complete failure of
the Reheat/Air Conditioning portion is the respon-
sibility of the installing contractor. Precautions
should be put into place to avoid these coils from
freezing or causing the motors to overheat or any
other unforeseen problem not mentioned here.
The coil is designed to temper the air delivered
through the HRV, to room temperature and is not
a heating appliance for the space.
Special care and attention should be given to
selecting a thermostat which will be connected to
the pump feeding the coil. The thermostats
function will be to signal the pump to send water
through the system if temperatures drop below
40˚F (5˚C) to prevent the coil from freezing and
also to shut the pump off if the air temperature
leaving the coil exceeds 77˚F (25˚C) to prevent
over heating motors.
The DX Coil is supplied with an orificing device
suitable for 1.5 tons of air conditioning @ 95˚F
80% RH inlet air.
Thermostats and pumps not available from NUTECH.
19
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Pitot Tube Air Flow Balancing
It is necessary to have balanced air flows in an HRV. The volume of
air brought in from the outside must equal the volume of air exhaust-
ed by the unit. If the air flows are not properly balanced, then;
Insert the Pitot tube into the duct; pointing the tip into the airflow.
For general balancing it is sufficient to move the pitot tube around in
the duct and take an average or typical reading. Repeat this proce-
dure in the other (supply or return) duct. Determine which duct has the
highest airflow (highest reading on the gauge). Then damper that air-
flow back to match the lower reading from the other duct. The flows
should now be balanced. Actual airflow can be determined from the
gauge reading. The value read on the gauge is called the velocity
pressure. The Pitot tube comes with a chart that will give the air flow
velocity based on the velocity pressure indicated by the gauge. This
velocity will be in either feet per minute or metres per second. To
determine the actual airflow, the velocity is multiplied by the cross
sectional area of the duct being measured.
• The HRV may not operate at its maximum efficiency
• A negative or positive air pressure may occur in the house
• The unit may not defrost properly
• Failure to balance HRV properly may void warranty
Excessive positive pressure may drive moist indoor air into the
external walls of the building where it may condense (in cold weather)
and degrade structural components. May also cause key holes to
freeze up.
Excessive negative pressure may have several undesirable effects.
In some geographic locations, soil gases such as methane and radon
gas may be drawn into the home through basement/ground contact
areas. Excessive negative pressure may also cause the backdrafting
of vented combustion equipment.
This is an example for determining the airflow in a 6" duct.
The Pitot tube reading was 0.025 inches of water.
From the chart, this is 640 feet per minute.
The 6" duct has a cross sectional area of = [3.14 x (6"÷12)2]÷4
= 0.2 square feet
Read the Application Warning on the front of this manual!
Prior to balancing, ensure that:
1. All sealing of the ductwork system has been completed.
2. All of the HRV's components are in place and functioning properly.
3. Balancing dampers are fully open.
The airflow is then:
640 ft./min. X 0.2 square feet = 128 cfm
For your convenience, the cross sectional area of some common
round duct is listed below:
DUCT DIAM. (inches)
CROSS SECTION AREA (sq. ft.)
4. Unit is on HIGH speed.
5
6
7
0.14
0.20
0.27
5. Air flows in branch lines to specific areas of the house should be
adjusted first prior to balancing the unit. A smoke pencil used at
thegrilles is a good indicator of each branch line's relative air flow.
6. After taking readings of both the stale air to the HRV duct and
fresh air to the house duct, the duct with the lower CFM ([L/s]
velocity) reading should be left alone, while the duct with the higher
reading should be dampered back to match the lower reading.
The accuracy of the air flow reading will be affected by how close to
any elbows or bends the readings are taken. Accuracy can be
increased by taking an average of multiple readings as outlined in the
literature supplied with the Pitot tube.
7. Return unit to appropriate fan speed for normal operation
Pitot tube and gauge
Balancing Procedure
The following is a method of field balancing an HRV using a Pitot
tube, advantageous in situations when flow stations are not installed
in the ductwork. Procedure should be performed with the HRV on high
speed.
DUCT
AIR FLOW
Pitot Tube Air Flow
The first step is to operate all mechanical systems on high speed,
which have an influence on the ventilation system, i.e. the HRV itself
and the forced air furnace or air handler if applicable. This will provide
the maximum pressure that the HRV will need to overcome, and allow
for a more accurate balance of the unit.
Balancing Kit
Pitot tube
c/w magnehelic gauge,
Pitot tube, hose and
carry case.
PART NO. 99-167
Magnehelic gauge
Drill a small hole in the duct (about 3/16"), three feet downstream of
any elbows or bends, and one foot
upstream of any elbows or bends.
Place pitot tube a minimum of 18" from blower or elbows
These are recommended distances
but the actual installation may limit the
amount of straight duct.
Outdoors
HRV must be in ventilate
mode when balancing
proceedure is performed
The Pitot tube should be connected to
a
magnehelic gauge or other
manometer capable of reading from 0
to 0.25 in. (0-62 Pa) of water, prefer-
ably to 3 digits of resolution. The tube
coming out of the top of the pitot is
connected to the high pressure side of
the gauge. The tube coming out of the
side of the pitot is connected to the
low pressure or reference side of the
gauge.
Pitot
tube
Magnehelic
gauge
Pitot
tube
Magnehelic
gauge
Note: Duct connections may vary,
depending on model.
20
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Service/Maintenance
Servicing your HRV on a regular schedule will
result in optimum operating efficiencies and
prolonged life of the equipment.
HRV Core
The heat exchange core is accessible through the
front service door. Special care and attention should
be given to this component as the edges may be
sharp, and the core itself susceptible to damage
if dropped.
Due to numerous applications in which this
equipment can be installed, it is difficult to predict
servicing intervals. In certain situations where there
is heavy smoke, servicing the equipment every one -
two months may be needed; whereas ventilating a
meeting room for example for carbon dioxide may
only need service every six months to a year.
When removing the core, the location it is removed
from should be noted.
The core is removed by carefully pulling the core out-
ward from the unit, sliding it evenly along its “H chan-
nel” supports found in each corner of the core. Note
the core may have some resistance when
sliding out. Avoid tilting the core as this will result in
its edges catching the H channel and temporarily
preventing its removal.
Motor
Access to the motor is through the front service
doors. Note heat exchanger core can be removed to
provide more room. See CORE in this section.
The motor is a permanent split capacitor type (PSC)
which uses a sleeve mechanism to steady the shaft.
There is an oil wick beside the sleeve which supplies
oil to it on a continuous basis.
In most cases, washing the core in a mild
detergent and warm water will be all that
is needed to completely clean them. Do not use
harsh chemicals as this may cause corrosion in the
HRV. The time between core service will depend
on the application the HRV has been installed in.
It can be as often as one - two months or at the very
least, cleaned every six months. When reinstalling
the core you must note foam location and drip
edge location for proper core placement.
If the motor does not have oil tubes, no maintenance
is required.
Access to the wick is through oil tubes, (two per
motor) located in the motor case itself. These oil
tubes are either capped with yellow plugs, (which
need to be removed for oiling) or have clear tubes
protruding from them.
See diagram below.
In either case an oiling device such as an “Oil
Telespout” filled with 20 S.A.E. non-detergent electric
motor oil should be used to put oil inside the tubes. A
couple of drops of oil once a year will do.
DO NOT OVER OIL!
Models 700, 1200 and 1000
FILTER
DOUBLE
DRIP EDGE
CORE
DOUBLE
DRIP
EDGES
FILTER
DRAIN PANS (
Note location and arrangement of cores and filters when removing.
21
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FILTERS
DUCT WORK
Open front service door to access the filters
located in both supply and exhaust air streams.
Note to remove and install filters, it may be easier
to first remove the core(s). See CORE.
It is a good idea to inspect ducting, outside
weather hoods (wall caps), and grilles for blockage
and dirt buildup, at least every six months.
Outside weather hoods should be protected by a
rodent screen which can plug up with debris.
Also, it is a good idea to visually confirm that
the fresh air supply is free from any sources of
contamination, such as other vented combustion
equipment added after the fact.
The filters are designed to stop large particles
from entering in the core. The filters are fastened
in place by a metal spring rod. To remove filters
from core(s) simply pull the rod from one end,
outward until free from core lip, and remove.
Only use warm water with a mild detergent to
wash the filters. Do not use harsh chemicals.
DAMPER MOTOR
The damper motor, (if applicable) is a self
contained motor and does not require service.
The damper door attached to the motor could use
a little lithium grease on the shaft opposite the
motor, where it enters its holder, once every
two - three years.
The time between filter service will depend on the
application the HRV has been installed in. It can
be as often as one - two months or at the very
least, cleaned every six months.
CONDENSATE DRAINS
The condensate drains consist of two drain pans General Maintenance
which may collect water after the HRV initiates a
defrost cycle, and a drain line to remove the
condensate.
As a final step in a routine maintenance
schedule, it is a good idea to confirm operation of
the system, checking speed control functions and
remote control operation, if applicable.
Maintenance on this portion of the system should
be done as often as possible and should not
exceed six months. Note bacterial growth in
standing water is a major concern to healthy
indoor air quality, and should be avoided whenever
possible.
Wipe the inside of the cabinet to remove dust and
cob webs as needed.
It is a good idea to keep a service/maintenance
log of the unit.
To clean these components, open the front
service door and flush the pans with water.
Ensure that the pans drain completely and in a
reasonable amount of time. Note if the water
does not drain right away, check for blockage in
the drain line, also check that the drain line has a
good slope to it. (1/8 - 1/4” per foot)
The drain line itself should have a “P” trap in it
below the HRV which is to be filled with water to
prevent odours or gases from entering back into
the unit. When flushing out the drain pans, this
too will be flushed out, and the water that was
there will be replaced with clean water.
22
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Troubleshooting Your HRV System
SYMPTOM
CAUSE
SOLUTION
Poor Air Flows
• 1/4” (6 mm) mesh on the outside hoods is plugged
• filters plugged
• clean exterior hoods or vents
• remove and clean filter
• core obstructed
• remove and clean core
• house grilles closed or blocked
• dampers are closed if installed
• poor power supply at site
• ductwork is restricting HRV
• improper speed control setting
• HRV airflow improperly balanced
• check and open grilles
• open and adjust dampers
• have electrician check supply voltage at house
• check duct installation
• increase the speed of the HRV
• have contractor balance HRV
Supply air feels cold
• poor location of supply grilles, the airflow may irritate
the occupant
• locate the grilles high on the walls or under the baseboards,
install ceiling mounted diffuser or grilles so as not to directly
spill the supply air on the occupant (eg. over a sofa)
• turn down the HRV supply speed. A small duct heater
(1kw) could be used to temper the supply air
• placement of furniture or closed doors is restricting the
movement of air in the home
• outdoor temperature extremely cold
• if supply air is ducted into furnace return, the furnace fan
may need to run continuously to distribute ventilation
air comfortably
Dehumidistat is not Operating
• improper low voltage connection
• external low voltage is shortened out by a staple or nail
• check dehumidistat setting it may be on OFF
• check that the correct terminals have been used
• check external wiring for a short
• set the dehumidistat at the desired setting
Humidity Levels are too High
• dehumidistat is set too high
• set dehumidistat lower
Condensation is appearing on the windows
• HRV is undersized to handle a hot tub, indoor pool, etc.
• lifestyle of the occupants
• cover pools, hot tubs when they are not in use
• avoid hanging clothes to dry, storing wood and venting clothes
dryer inside. Heating wood may have to be moved outside
• vent crawl space and place a vapour barrier on the floor
of the crawl space
• moisture coming into the home from an unvented or
unheated crawl space
• moisture is remaining in the washroom and kitchen areas
• ducts from the washroom should be sized to remove moist
air as effectively as possible, use of a bathroom fan for
short periods will remove additional moisture
• on humid days, as the seasons change, some condensation
may appear but the homes air quality will remain high with
some HRV use
• condensation seems to form in the spring and fall
• HRV is set at too low a speed
• increase speed of the HRV
Humidity Levels are too Low
• dehumidistat control set too low
• blower speed of HRV is too high
• lifestyle of occupants
• set dehumidistat higher
• decrease HRV blower speed
• humidity may have to be added through the use of humidifiers
• have a contractor balance HRV airflows
• HRV air flows may be improperly balanced
HRV and / or Ducts Frosting up
• Note: minimal frost build-up is expected on cores before
unit initiates defrost cycle functions
• HRV air flows are improperly balanced
• malfunction of the HRV defrost system
• have HVAC contractor balance the HRV
• using the self-test feature at the Base Module, press the fan
control symbol, the damper defrost unit should cycle its full
travel when working properly.
Condensation or Ice Build Up in Insulated Duct to
the Outside
• incomplete vapour barrier around insulated duct
• a hole or tear in outer duct covering
• tape and seal all joints
• tape any holes or tears made in the outer duct covering
• ensure that the vapour barrier is completely sealed
Water in the bottom of the HRV
• drain pans plugged
• improper connection of HRVs drain lines
• HRV is not level
• ensure O-Ring on drain nozzle sits properly
• look for kinks in line
• check water drain connections
• drain lines are obstructed
• HRV heat exchange core is not properly installed
23
• make sure water drains properly from pan
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DfeondSwitch
CralngSwitch
N
B R O W
B L A C K
B L A C K
H I W T E
H I W T E
B L A C K
H I W T E
B L A C K
H I W T E
B L A C K
H I W T E
B L A C K
O R A N G E
H I W T E
H I W T E
O R A N G E
O R A N G E
B L U E
R E D
B L A C K
O R A N G E
Y E L L O W
W H I T E
C A P A C I T O R S
F A N M O T O R
H I W T E
B L A C K
B L A C K
H I W T E
C A P A C I T O R S
F A N M O T O R
B L U E
R E D
H I W T E
B L A C K
B L U E
B L A C K
R E D
B L U E
B L A C K
R E D
R E D
H I W T E
Y E L L O W
B L U E
B L A C K
24
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COMMERCIAL LIFEBREATH®
HEAT RECOVERY VENTILATORS
• Two Year Limited Warranty • 15 Year Core Warranty
®
®
NUTECH BRANDS INC. (NUTECH) warrants to the purchaser of the Commercial LIFEBREATH
model and accessories referred to below, to be free from manufacturing defects.
®
This Warranty is personal to NUTECH and is in effect from the date of the original purchase for a
®
period of two years, save and except that a 15 YEAR WARRANTY is given to the LIFEBREATH
core should it develop a condensation leak or become perforated due to corrosion caused by nor-
mal use.
Damage resulting from all other causes, including but not limited to: lighting, hurricane, tornado,
earthquake or any other acts of God; improper installation, modification, alteration or misuse of the
®
LIFEBREATH or its operation in a manner contrary to the instructions accompanying the unit at
the time of sale; accidental or intentional damage, neglect, improper care, or other failure by the
owner to provide reasonable and necessary maintenance of the product; any attempt at repair by
an unauthorized service representative or not in accordance with this warranty; or any other causes
®
beyond the control of NUTECH , are excluded from this warranty.
®
If you feel that the LIFEBREATH you purchased is not free from manufacturing defects, please
®
contact NUTECH BRANDS INC. , 511 McCormick Blvd., London, Ontario N5W 4C8, 519-457-1904
or fax 519-457-1676 to find the name of your nearest dealer in order to repair the product. The
labour required to install any replacement part(s) shall be dealt with at the option of the customer in
either of the following ways:
(a) the customer may supply labour at their own expense: or
(b) if the product was purchased from a dealer, then the dealer
will supply labour at cost to the customer.
®
NUTECH reserves the right to replace the entire unit or to refund the original purchase price in lieu
of repair.
®
NUTECH MAKES NO EXPRESS WARRANTIES, EXCEPT FOR THOSE THAT ARE SET
FORTH HEREIN AND SHALL NOT BE LIABLE FOR ANY INCIDENTAL, SPECIAL OR CONSE-
®
QUENTIAL DAMAGES WITH RESPECT TO LIFEBREATH COVERED BY THIS WARRANTY.
NUTECH’S COMPLETE LIABILITY AND THE OWNER’S EXCLUSIVE REMEDY BEING LIMITED
TO REPAIR OR REPLACEMENT ON THE TERMS STATED HEREIN. ANY IMPLIED WAR-
RANTIES, INCLUDING BUT NOT LIMITED TO THE IMPLIED WARRANTY OF MER-
CHANTABILITY AND OF FITNESS FOR ANY PARTICULAR PURPOSE, ARE EXPRESSLY
EXCLUDED.
NO PERSON IS AUTHORIZED TO CHANGE THE WARRANTY IN ANY WAY OR GRANT ANY
OTHER WARRANTY UNLESS SUCH CHANGES ARE MADE IN WRITING AND SIGNED BY AN
®
OFFICER OF NUTECH .
MODEL NO.: ____________________________________________________________________
UNIT SERIAL NO.: _______________________________________________________________
INSTALLED BY: _________________________________________________________________
DATE: _________________________________________________________________________
TI-38
25
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