AQUAZONE™
50HQP072-120
Horizontal Water Source Heat Pumps
with PURON® Refrigerant (R-410A)
50 Hz
Installation, Start-Up, and
Service Instructions
Page
CONTENTS
Antifreeze . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
Cooling Tower/Boiler Systems . . . . . . . . . . . . . . . . . . 24
Ground Coupled, Closed Loop and Plateframe
Heat Exchanger Well Systems . . . . . . . . . . . . . . . . 24
OPERATION. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .24,25
Power Up Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
Units with Aquazone Complete C Control . . . . . . . 24
Units with Aquazone Deluxe D Control . . . . . . . . . . 24
SYSTEM TEST . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .25,26
Test Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
Retry Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
Aquazone Deluxe D Control LED Indicators . . . . . 25
SERVICE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26-29
Filters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
Water Coil. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
Condensate Drain Pans . . . . . . . . . . . . . . . . . . . . . . . . . 27
Refrigerant System. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
Condensate Drain Cleaning . . . . . . . . . . . . . . . . . . . . . 27
Air Coil Cleaning . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
Condenser Cleaning . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
Compressor. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
Fan Motors. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
Belt . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
Air Coil. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
Checking System Charge . . . . . . . . . . . . . . . . . . . . . . . 28
Refrigerant Charging. . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
Air Coil Fan Motor Removal . . . . . . . . . . . . . . . . . . . . . 28
Blower Fan Sheaves . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
Blower Fan Performance Adjustment . . . . . . . . . . . 29
Page
SAFETY CONSIDERATIONS . . . . . . . . . . . . . . . . . . .1,2
GENERAL. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
INSTALLATION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-15
Step 1 — Check Jobsite . . . . . . . . . . . . . . . . . . . . . . . . 2
Step 2 — Check Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
• STORAGE
• PROTECTION
• INSPECT UNIT
Step 3 — Locate Unit. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
Step 4 — Mount Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
Step 5 — Install Duct System. . . . . . . . . . . . . . . . . . . . . 5
• SOUND ATTENUATION
• EXISTING DUCT SYSTEM
Step 6 — Install Condensate Piping Drain. . . . . . . . 6
• INSTALLATION
• VENTING
Step 7 — Field Convert Air Discharge . . . . . . . . . . . . 6
Step 8 — Install Piping Connections . . . . . . . . . . . . . 7
• WATER LOOP APPLICATIONS
• GROUND-LOOP APPLICATIONS
• GROUND-WATER APPLICATIONS
Step 9 — Install Field Power Supply Wiring . . . . . . 8
• POWER CONNECTION
• SUPPLY VOLTAGE
• EXTERNAL LOOP POWER CONNECTION
• 420-VOLT OPERATION
Step 10 — Install Field Control Wiring. . . . . . . . . . . 15
• THERMOSTAT CONNECTIONS
TROUBLESHOOTING . . . . . . . . . . . . . . . . . . . . . . . . 30-32
Thermistor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
Control Sensors. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
• WATER FREEZE PROTECTION
• AIR COIL FREEZE PROTECTION
• ACCESSORY CONNECTIONS
• WATER SOLENOID VALVES
START-UP CHECKLIST . . . . . . . . . . . . . . . . . . . CL-1,CL-2
PRE-START-UP. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16-20
System Checkout. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
Airflow and External Static Pressure . . . . . . . . . . . 16
IMPORTANT: Read the entire instruction manual before
starting installation.
FIELD SELECTABLE INPUTS . . . . . . . . . . . . . . . 20-22
Complete C Control Jumper Settings. . . . . . . . . . . 20
Complete C Control DIP Switches. . . . . . . . . . . . . . 20
Deluxe D Control Jumper Settings . . . . . . . . . . . . . 20
Deluxe D Control DIP Switches . . . . . . . . . . . . . . . . 21
Deluxe D Control Accessory Relay
SAFETY CONSIDERATIONS
Installation and servicing of air-conditioning equipment can
be hazardous due to system pressure and electrical compo-
nents. Only trained and qualified service personnel should
install, repair, or service air-conditioning equipment.
Untrained personnel can perform basic maintenance func-
tions of cleaning coils and filters and replacing filters. All other
operations should be performed by trained service personnel.
When working on air-conditioning equipment, observe precau-
tions in the literature, tags and labels attached to the unit, and
other safety precautions that may apply.
Improper installation, adjustment, alteration, service, main-
tenance, or use can cause explosion, fire, electrical shock or
other conditions which may cause personal injury or property
damage. Consult a qualified installer, service agency, or your
distributor or branch for information or assistance. The
qualified installer or agency must use factory-authorized kits or
Configurations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
START-UP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22-24
Operating Limits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
Air Coil Cleaning . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
Start Up System. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
Scroll Compressor Rotation. . . . . . . . . . . . . . . . . . . . . 22
Unit Start-Up in Cooling Mode. . . . . . . . . . . . . . . . . . . 22
Unit Start-Up in Heating Mode. . . . . . . . . . . . . . . . . . . 23
Flow Regulation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
Flushing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
Manufacturer reserves the right to discontinue, or change at any time, specifications or designs without notice and without incurring obligations.
Catalog No. 04-53500077-01 Printed in U.S.A. Form 50HQP-C1SI Pg 1 11-10 Replaces: New
especially important in areas where painting, plastering, or
spraying of fireproof material, etc. is not yet complete. Foreign
material that is allowed to accumulate within the units can pre-
vent proper start-up and necessitate costly clean-up operations.
3. Verify that the unit’s refrigerant tubing is free of kinks or
dents, and that it does not touch other unit components.
4. Inspect all electrical connections. Be sure connections are
clean and tight at their terminations.
Before installing any of the system components, be sure to
examine each pipe, fitting, and valve, and remove any dirt or
foreign material found in or on these components.
5. Loosen compressor bolts until the compressor rides freely
on springs. Remove shipping restraints.
6. Remove the four 6 mm (1/4 in.) shipping bolts from com-
pressor support plate (two bolts on each side) to maxi-
mize vibration and sound alternation.
CAUTION
DO NOT store or install units in corrosive environments or
in locations subject to temperature or humidity extremes
(e.g., attics, garages, rooftops, etc.). Corrosive conditions
and high temperature or humidity can significantly reduce
performance, reliability, and service life. Always move
units in an upright position. Tilting units on their sides may
cause equipment damage.
CAUTION
Failure to remove shipping brackets from spring-mounted
compressors will cause excessive noise and could cause
component failure due to added vibration.
7. Remove any blower support cardboard from inlet of the
blower.
INSPECT UNIT — To prepare the unit for installation, com-
plete the procedures listed below:
8. Locate and verify any accessory kit located in compressor
and/or blower section.
1. Compare the electrical data on the unit nameplate with
ordering and shipping information to verify that the
correct unit has been shipped.
9. Remove any access panel screws that may be difficult to
remove once unit is installed.
2. Do not remove the packaging until the unit is ready for
installation.
Table 1 — Physical Data — 50HQP072-120 Units
UNIT 50HQP
COMPRESSOR QUANTITY*
Number of Circuits (Compressors)
Factory Charge HFC-410A (kg) per circuit
BLOWER MOTOR
072
096
Scroll
2
120
2.27
2.24
1.70
0.75
2.15
Blower Motor Quantity
Standard Motor (kW)
1
1.49
BLOWER
No. of Blowers
1
Blower Wheel Size D x W (cm)
WATER CONNECTION SIZE
FPT (in.) [mm]
COAX VOLUME
Volume (liters)
30.48 x 30.48
11/4 [31.8]
11/2 [38.1]
9.08
6.13
6.85
CONDENSATE CONNECTION SIZE
FPT (in.) [mm]
3/4 [19.1]
AIR COIL DATA
Air Coil Dimensions H x W (cm)
Air Coil Total Face Area (sq m)
Air Coil Tube Size (cm)
Air Coil Fin Spacing (fins per cm)
Air Coil Number of Rows
MISCELLANEOUS DATA
Filter Standard - Throwaway (qty) (cm)†
Weight - Operating (kg)
Weight - Packaged (kg)
50.8 x 137.16
0.70
50.8 x 162.56
0.83
0.953
5.5
3
40.64 x 50.80 x 2.54
265.8
283.9
292.1
310.3
316.6
334.8
*All units have grommet and spring compressor mountings, and
2.2 mm and 3.5 mm electrical knockouts.
NOTE: Use the lowest maximum pressure rating when multiple
options are combined:
†51 mm filters are available as field-installed accessory.
OPTION
MAXIMUM PRESSURE (kPa)
Base Unit
3100
3
RIGHT RETURN STRAIGHT DISCHARGE
BSP
LEFT RETURN STRAIGHT DISCHARGE
BSP
A
B
C
CBP
1
CAP
5
4
F
D
1
E
G
EAP
EAP
O
2
CAP
CBP
K
2
CAP
CAP
FRONT
M
P
Q
FRONT
R
LEGEND
SERVICE ACCESS
3’ (91 cm.) TYPICAL
ALL CONFIGURATIONS
BSP — Blower Service Panel
CAP — Control Access Panel
CBP — Control Box Panel
EAP — Expansion Valve Access Panel
NOTES:
1. All dimensions in centimeters, unless indicated.
2. Access is required for all removable panels and installer should
take care to comply with all building codes and allow adequate
clearance.
3. Water inlet and outlet connections are available on either side of
the unit. Plugs are shipped loose in a plastic bag tied to the water
leg in front of the unit. Installer must plug unused connection.
4. Condensate drain connection is on end opposite of comressor.
5. Electrical access is available on either side of the front of the unit.
6. Electrical box is on right side but can be field-converted to left.
221cm
HANGER BRACKET DIMENSIONS
CONTROL BOX
2.54cm
PLAN VIEW
TOP
PLAN VIEW
TOP
86.6cm
3
10.8cm
CONNECTIONS
1
CONTROL BOX
1 / FPT (072,096)
4
1
2
3
4
5
Water Outlet
1
1 / FPT (120)
2
U
V
S
V
S
U
1
1 / FPT (072,096)
4
Water Inlet
1
1 / FPT (120)
2
T
Condensate
Drain
3
/ FPT
4
3.3cm
condensate
RIGHT RETURN RIGHT VIEW-
LEFT RETURN LEFT VIEW-
High Voltage
Access
3.3cm
condensate drain
1
AIR COIL SIDE
1 / K.O.
8
AIR COIL SIDE
Low Voltage
Access
7
/ K.O.
8
RIGHT RETURN END DISCHARGE
LEFT RETURN END DISCHARGE
CAP
CAP
CAP
CBP
FRONT
FRONT
EAP
EAP
CAP
CBP
BSP
BSP
E
D
F
G
50-8531
OVERALL
CABINET
(cm)
DISCHARGE
WATER
ELECTRICAL
KNOCKOUTS
(cm)
RETURN AIR
CONNECTIONS (cm)
CONNECTIONS
(cm)
CONNECTIONS (cm)
(Duct Flange [ 0.1 cm])
(Using Return Air Opening)
UNIT
50HQP
E
F
S
T
A
B
C
D
SupplySupply
Depth Height
G
K
L
M
O
P
Q
R
Return Return
Depth Height
U
V
Depth Width Height
072-120 92.2 215.6 54.9 35.6 43.2 34.3 19.8 38.1 21.1 10.2 5.1 47.8 42.7 35.1 165.1
45.7 2.5 48.0
Fig. 1 — Unit Dimensions
4
NOTES:
1. Access is required for all removable panels and installer should
take care to comply with all building codes and allow adequate
clearance.
2. Water inlet and outlet connections are available on either side of
the unit. Plugs are shipped loose in a plastic bag tied to the water
leg in front of the unit. Installer must plug unused connection.
3. Condensate drain connection is on end opposite of compressor.
4. Electrical access is available on either side of the front of the unit.
5. Electrical box is on right side but can be field-converted to left.
LEGEND
BSP — Blower Service Panel
CAP — Control Access Panel
CBP — Control Box Panel
EAP — Expansion Valve Access Panel
a50-8534
Fig. 2 — Typical Horizontal Installation
of hanging rods to building structure is critical for safety. See
Fig. 2. Rod attachments must be able to support the weight of
the unit. See Table 1 for unit operating weights.
Step 3 — Locate Unit — The following guidelines
should be considered when choosing a location for a WSHP:
• Units are for indoor use only.
• Locate in areas where ambient temperatures are between
4.4 C and 37.8 C and relative humidity is no greater than
75%.
• Provide sufficient space for water, electrical and duct
connections.
• Locate unit in an area that allows for easy access and
removal of filter and access panels.
• Allow enough space for service personnel to perform
maintenance.
• Provisions must be made for return air to freely enter the
space if unit needs to be installed in a confined area such
as a closet.
NOTE: Correct placement of the horizontal unit can play an
important part in minimizing sound problems. Since duct-
work is normally applied to these units, the unit can be placed
so that the principal sound emission is outside the occupied
space in sound-critical applications. A fire damper may be re-
quired by the local code if a fire wall is penetrated.
Step 5 — Install Duct System — The duct system
should be sized to handle the design airflow quietly.
NOTE: Depending on the unit, the fan wheel may have a ship-
ping support installed at the factory. This must be removed
before operating unit.
SOUND ATTENUATION — To eliminate the transfer of
vibration to the duct system, a flexible connector is recom-
mended for both discharge and return air duct connections on
metal duct systems. The supply and return plenums should in-
clude internal duct liner of fiberglass or be made of duct board
construction to maximize sound attenuation of the blower.
Installing the WSHP unit to uninsulated ductwork in an uncon-
ditioned space is not recommended since it will sweat and
adversely affect the unit’s performance.
To reduce air noise, at least one 90-degree elbow could be
included in the supply and return air ducts, provided system
performance is not adversely impacted. The blower speed can
be also changed in the field to reduce air noise or excessive air-
flow, provided system performance is not adversely impacted.
Step 4 — Mount Unit — Units should be mounted us-
ing the factory-installed hangers. See Fig. 3. Proper attachment
5
EXISTING DUCT SYSTEM — If the unit is connected to
existing ductwork, consider the following:
• Verify that the existing ducts have the proper capacity to
handle the unit airflow. If the ductwork is too small,
larger ductwork should be installed.
• Check existing ductwork for leaks and repair as
necessary.
1/4” Pitch for
Drainage
NOTE: Local codes may require ventilation air to enter the
space for proper indoor air quality. Hard-duct ventilation may
be required for the ventilating air supply. If hard ducted venti-
lation is not required, be sure that a proper air path is provided
for ventilation air to unit to meet ventilation requirement of the
space.
Step 6 — Install Condensate Piping Drain
Pitch Toward
Drain
INSTALLATION — Slope the unit toward the drain at a
1 cm per 50 cm pitch. See Fig. 4. If it is not possible to meet the
required pitch, a condensate pump should be installed at the
unit to pump condensate to building drain.
Install condensate trap at each unit with the top of the trap
positioned below the unit condensate drain connection as
shown in Fig. 5. Design the depth of the trap (water-seal) based
upon the amount of ESP (external static pressure) capability of
the blower (where 2 in. wg of ESP capability requires 2 in. of
trap depth). As a general rule, 38 mm trap depth is the mini-
mum. Each unit must be installed with its own individual trap
and connection to the condensate line (main) or riser.
Drain Connection
a50-6260ef8536
Fig. 4 — Horizontal Unit Pitch
Units are not internally trapped, therefore an external trap is
necessary. Each unit must be installed with its own individual
trap and means to flush or blowout the condensate drain line.
Do not install units with a common trap or vent. For typical
condensate connections see Fig. 5.
Vent
*3/4" IPT
Trap Depth
1.5" [38mm]
Min 1.5"
[38mm]
NOTE: Never use a pipe size smaller than the connection.
VENTING — A vent should be installed in the condensate
line of any application which may allow dirt or air to collect in
the line. Consider the following:
3/4" PVC or
Copper by others
1/4" per foot
(21mm per m)
drain slope
a50-6260e8537
• Always install a vent where an application requires a
long horizontal run.
Fig. 5 — Trap Condensate Drain
• Always install a vent where large units are working
against higher external static pressure and to allow
proper drainage for multiple units connected to the same
condensate main.
Step 7 — Field Convert Air Discharge — Hori-
zontal units can be field converted between straight (side) and
back (end) discharge.
NOTE: It is not possible to field convert return air between left
or right return models due to the necessity of refrigeration cop-
per piping changes.
Field conversion must be completed on the ground. If the
unit is already hung it should be taken down for the field con-
version. Place in a well-lighted area. Conversion should only
be attempted by a qualified service technician.
• Be sure to support the line where anticipated sagging
from the condensate or when “double trapping” may
occur.
• If condensate pump is present on unit, be sure drain con-
nections have a check valve to prevent back flow of con-
densate into other units.
3/8" [10MM] THREADED
ROD (FIELD SUPPLIED)
SIDE TO BACK DISCHARGE CONVERSION
VIBRATION ISOLATOR
(FACTORY SUPPLIED)
1. Remove back panel and side access panel. See Fig. 6.
2. Loosen 2 motor slide nuts, raise motor slide assembly and
remove belt and motor sheave. See Fig. 7.
3. Remove blower sheave. Remove motor bolts and careful-
ly remove motor. See Fig. 8.
4. Remove 2 motor clips and reattach to opposite side. See
Fig. 9.
5. Unbolt (3 per side) complete housing assembly. See
Fig. 9.
WASHER
(FIELD SUPPLIED)
DOUBLE HEX NUTS
(FIELD SUPPLIED)
6. Rotate complete assembly into new position. Locate over
mounting holes in base, reattach using 3 bolts per side.
a50-6260e8535
Fig. 3 — Hanger Brackets
6
FRONT
RETURN AIR
REMOVE MOTOR
AND BLOWER SHEAVE
ADJUSTING BOLT
REMOVE 4
MOTOR BOLTS
a50-8538
REMOVE BLOWER PANEL
AND ACCESS PANEL
Fig. 6 — Removing Panels
a50-8540
Fig. 8 — Removing Motor
MOTOR SLIDE NUTS
MOTOR CLIPS
a50-8539
Fig. 7 — Removing Belt
7. Mount motor, motor sheave, blower sheave and belt.
Make sure wires are not pinched and not over sharp edg-
es. Adjust motor downward to tighten belt. Raise or lower
motor slide assembly with adjusting bolt and retighten the
2 slide nuts. Check for correct tension. Rewire motor (at
contactor) for correct rotation. Spin blower wheel to en-
sure wheel is not obstructed.
a50-8541
BOLTS
Fig. 9 — Removing Blower Assembly
8. Replace panels from Step 1.
• Insulation may be required on piping to avoid condensa-
tion in the case where fluid in loop piping operates at
temperatures below dew point of adjacent air.
• Piping systems that contain steel pipes or fittings may
be subject to galvanic corrosion. Dielectric fittings may
be used to isolate the steel parts of the system to avoid
galvanic corrosion.
• Do not allow hoses to rest against structural building
components. Compressor vibration may be transmitted
through the hoses to the structure, causing unnecessary
noise complaints.
BACK TO SIDE DISCHARGE CONVERSION — If the
discharge is changed from back to side, use the above instruc-
tions. Note that figures will be reversed.
LEFT OR RIGHT RETURN UNITS — It is not possible to
field convert return air between left or right return units due to
the necessity of refrigeration copper piping changes. However,
the conversion process of side to back or back to side discharge
for either right or left return configuration is the same. In some
cases, it may be possible to rotate the entire unit 180 degrees if
the return air connection needs to be on the opposite side. Note
that rotating the unit will move the piping to the other end of
the unit.
Figure 10 shows a typical supply/return hose kit assembly.
WATER LOOP APPLICATIONS — Water loop applications
usually include a number of units plumbed to a common pip-
ing system. Maintenance to any of these units can introduce air
into the piping system. Therefore, air elimination equipment
comprises a major portion of the mechanical room plumbing.
The flow rate is usually set between 2.41 and 3.23 L/m per
kW of cooling capacity. For proper maintenance and servicing,
pressure-temperature (P/T) ports are necessary for temperature
and flow verification.
In addition to complying with any applicable codes, consid-
er the following for system piping:
• Piping systems utilizing water temperatures below
10 C require 13 mm closed cell insulation on all piping
surfaces to eliminate condensation.
Step 8 — Install Piping Connections — Depend-
ing on the application, there are 3 types of WSHP piping sys-
tems to choose from: water loop, ground-water and ground loop.
Refer to the Carrier System Design Manual for additional infor-
mation.
All WSHP units utilize low temperature soldered female
pipe thread fittings for water connections to prevent annealing
and out-of-round leak problems which are typically associated
with high temperature brazed connections. Refer to Table 1 for
connection sizes. When making piping connections, consider
the following:
• A backup wrench must be used when making screw con-
nections to unit to prevent internal damage to piping.
7
Step 9 — Install Field Power Supply Wiring
WARNING
SWIVEL
BRASS
FITTING
BRASS
FITTING
RIB CRIMPED
LENGTH
Electrical shock can cause personal injury and death. Shut
off all power to this equipment during installation. There
may be more than one disconnect switch. Tag all discon-
nect locations to alert others not to restore power until work
is completed.
(2 FT [0.6M] LENGTH STANDARD)
EPT
Fig. 10 — Supply/Return Hose Kit
CAUTION
• All plastic to metal threaded fittings should be avoided
due to the potential to leak. Use a flange fitted substitute.
• Teflon tape thread sealant is recommended to minimize
internal fouling of the heat exchanger.
Use only copper conductors for field-installed electrical
wiring. Unit terminals are not designed to accept other
types of conductors.
• Use backup wrench. Do not overtighten connections.
• Route piping to avoid service access areas to unit.
• The piping system should be flushed prior to operation to
remove dirt and foreign materials from the system.
All field-installed wiring, including the electrical ground,
MUST comply with the National Electrical Code (NEC,
U.S.A.) as well as applicable local codes. In addition, all field
wiring must conform to the Class II temperature limitations de-
scribed in the NEC.
Refer to unit wiring diagrams Fig. 12-16 for fuse sizes and a
schematic of the field connections which must be made by the
installing (or electrical) contractor.
GROUND-LOOP APPLICATIONS — Temperatures be-
tween –3.9 and 43.3 C and a cooling capacity of 2.41 to
3.23 L/s per kW of flow per ton are recommended. In
addition to complying with any applicable codes, consider
the following for system piping:
Consult the unit wiring diagram located on the inside of the
compressor access panel to ensure proper electrical hookup.
The installing (or electrical) contractor must make the field
connections when using field-supplied disconnect.
• Piping materials should be limited to only polyethylene
fusion in the buried sections of the loop.
• Galvanized or steel fittings should not be used at any
time due to corrosion.
• All plastic to metal threaded fittings should be avoided
due to the potential to leak. Use a flange fitted substitute.
• Do not overtighten connections.
• Route piping to avoid service access areas to unit.
• Pressure-temperature (P/T) plugs should be used to mea-
sure flow of pressure drop.
GROUND-WATER APPLICATIONS — Typical ground-
water piping is shown in Fig. 11. In addition to complying
with any applicable codes, consider the following for sys-
tem piping:
• Install shut-off valves for servicing.
• Install pressure-temperature plugs to measure flow and
temperature.
• Boiler drains and other valves should be connected using
a “T” connector to allow acid flushing for the heat
exchanger.
• Do not overtighten connections.
• Route piping to avoid service access areas to unit.
• Use PVC SCH80 or copper piping material.
Operating voltage must be the same voltage and phase as
shown in electrical data shown in Tables 3A and 3B.
Make all final electrical connections with a length of flexi-
ble conduit to minimize vibration and sound transmission to
the building.
POWER CONNECTION — Line voltage connection is
made by connecting the incoming line voltage wires to the
L side of the power block terminal. See Fig. 17. See Tables
3A and 3B for correct wire and maximum overcurrent pro-
tection sizing. See Table 4 for low voltage VA ratings.
SUPPLY VOLTAGE — Operating voltage to unit must be
within voltage range indicated on unit nameplate.
On 3-phase units, voltages under load between phases must
be balanced within 2%. Use the following formula to deter-
mine the percentage voltage imbalance:
% Voltage Imbalance
max voltage deviation from average voltage
= 100 x
average voltage
NOTE: PVC SCH40 should not be used due to system high
pressure and temperature extremes.
Water Supply and Quantity — Check water supply. Water
supply should be plentiful and of good quality. See Table 2 for
water quality guidelines.
Example: Supply voltage is 420-3-50.
AB = 425 volts
BC = 422 volts
AC = 417 volts
IMPORTANT: Failure to comply with the above required
water quality and quantity limitations and the closed-
system application design requirements may cause damage
to the tube-in-tube heat exchanger that is not the responsi-
bility of the manufacturer.
425 + 422 + 417
Average Voltage =
3
1264
=
3
=
421
In all applications, the quality of the water circulated
through the heat exchanger must fall within the ranges listed in
the Water Quality Guidelines table. Consult a local water treat-
ment firm, independent testing facility, or local water authority
for specific recommendations to maintain water quality within
the published limits.
Determine maximum deviation from average voltage:
(AB) 425 – 421 = 4 v
(BC) 422 – 421 = 1 v
(AC) 421 – 418 = 3 v
Maximum deviation is 4 v.
8
Determine percent voltage imbalance.
NOTE: If more than 2% voltage imbalance is present, contact
local electric utility.
4
% Voltage Imbalance = 100 x
421
EXTERNAL LOOP POWER CONNECTION — If the unit
is to be connected to an external loop pump or flow controller,
connect the pump to the loop pump terminal block PB1. The
maximum power handling is 4 amps at 240 volts. The pumps
will automatically cycle as required by the unit.
= 0.95%
This amount of phase imbalance is satisfactory as it is
below the maximum allowable 2%.
420-VOLT OPERATION — All 380/420 volt units are factory
wired for 380 volts. The transformers may be switched to
420-volt operation (as illustrated on the wiring diagram) by
disconnecting the VIO lead at L1 and attaching the BRN lead
to L1. Close open end of VIO lead.
Operation on improper line voltage or excessive phase
imbalance constitutes abuse and may cause damage to electri-
cal components.
Water
Control
Valve
Automatic
Balance Valve
Expansion
Tank
Water Out
Water In
From Pump
Shut-Off
Valve
Strainer – Field-Installed Accessory
(16 to 20 mesh recommended for
filter sediment)
Boiler
Drains
Pressure-
Temperature
Plugs
a50-8542
Fig. 11 — Typical Ground-Water Piping Installation
9
Table 2 — Water Quality Guidelines
HX
MATERIAL*
CONDITION
CLOSED RECIRCULATING†
OPEN LOOP AND RECIRCULATING WELL**
Scaling Potential — Primary Measurement
Above the given limits, scaling is likely to occur. Scaling indexes should be calculated using the limits below.
pH/Calcium
Hardness Method
All
N/A
pH < 7.5 and Ca Hardness, <100 ppm
Index Limits for Probable Scaling Situations (Operation outside these limits is not recommended.)
Scaling indexes should be calculated at 150 F for direct use and HWG applications, and at 90 F for indirect HX use. A monitoring plan should be
implemented.
Ryznar Stability Index
6.0 - 7.5
If >7.5 minimize steel pipe use.
–0.5 to +0.5
All
N/A
Langelier Saturation Index
All
N/A
If <–0.5 minimize steel pipe use.
Based upon 150 F HWG and direct well, 85 F indirect well HX.
Iron Fouling
Iron Fe2+ (Ferrous)
<0.2 ppm (Ferrous)
If Fe2+ (ferrous) >0.2 ppm with pH 6 - 8, O2<5 ppm check for iron bacteria.
<0.5 ppm of Oxygen
All
All
N/A
N/A
(Bacterial Iron Potential)
Iron Fouling
Above this level deposition will occur.
Corrosion Prevention††
pH
6 - 8.5
Minimize steel pipe below 7 and no open tanks with pH <8.
<0.5 ppm
6 - 8.5
All
All
Monitor/treat as needed.
Hydrogen Sulfide (H2S)
At H2S>0.2 ppm, avoid use of copper and cupronickel piping or HXs.
Rotten egg smell appears at 0.5 ppm level.
Copper alloy (bronze or brass) cast components are okay to <0.5 ppm.
N/A
N/A
Ammonia Ion as Hydroxide,
Chloride, Nitrate and Sulfate
Compounds
<0.5 ppm
All
Maximum Chloride Levels
Maximum allowable at maximum water temperature.
50 F (10 C)
75 F (24 C)
100 F (38 C)
Copper
N/A
<20 ppm
<150 ppm
<400 ppm
<1000 ppm
>1000 ppm
NR
NR
CuproNickel
N/A
N/A
N/A
N/A
NR
NR
304 SS
<250 ppm
<550 ppm
>550 ppm
<150 ppm
<375 ppm
>375 ppm
316 SS
Titanium
Erosion and Clogging
Particulate Size and Erosion
<10 ppm of particles and a max-
imum velocity of 6 fps. Filtered
for maximum
<10 ppm (<1 ppm “sand free” for reinjection) of particles and a maximum velocity of 6
fps. Filtered for maximum 800 micron size. Any particulate that is not removed can
potentially clog components.
All
All
800 micron size.
Brackish
Use cupronickel heat exchanger when concentrations of calcium or sodium chloride
are greater than 125 ppm are present. (Seawater is approximately 25,000 ppm.)
N/A
LEGEND
Hot Water Generator
Heat Exchanger
††If the concentration of these corrosives exceeds the maximum allowable level,
then the potential for serious corrosion problems exists.
HWG
HX
—
—
—
Sulfides in the water quickly oxidize when exposed to air, requiring that no agitation
occur as the sample is taken. Unless tested immediately at the site, the sample will
require stabilization with a few drops of one Molar zinc acetate solution, allowing
accurate sulfide determination up to 24 hours after sampling. A low pH and high
alkalinity cause system problems, even when both values are within ranges shown.
The term pH refers to the acidity, basicity, or neutrality of the water supply. Below
7.0, the water is considered to be acidic. Above 7.0, water is considered to be basic.
Neutral water contains a pH of 7.0.
N/A
Design Limits Not Applicable Considering Recirculating
Potable Water
NR
SS
—
—
Application Not Recommended
Stainless Steel
*Heat exchanger materials considered are copper, cupronickel, 304 SS (stainless
steel), 316 SS, titanium.
†Closed recirculating system is identified by a closed pressurized piping system.
**Recirculating open wells should observe the open recirculating design
considerations.
NOTE: To convert ppm to grains per gallon, divide by 17. Hardness in mg/l is equiv-
alent to ppm.
10
Complete C1
Complete C2
Complete C
Complete C
Complete C1
Complete C2
LEGEND
BC
— Blower Contactor
— Circuit Breaker
Field Line Voltage Wiring
Field Low Voltage Wiring
Printed Circuit Trace
Optional Wiring
Ground
CB
CC
— Compressor Contactor
Solenoid Coil
CO
DPP
FP1
FP2
HP
— Sensor, Condensate Overflow
— Dual Point Power
— Sensor, Water Coil Freeze Protection
— Sensor, Air Coil Freeze Protection
— High-Pressure Switch
Relay Contacts - N.O.
Relay Contacts - N.C.
Temperature Switch
Switch - Low Pressure
Switch - High Pressure
Wire Nut
Relay/Contactor Coil
HPWR — High-Pressure Water Relay
Thermistor
JW3
LOC
PDB
RVS
— Clippable Field Selection Jumper
— Loss of Charge Pressure Switch
— Power Distribution Block
Condensate Pan
Circuit Breaker
— Reversing Valve Solenoid
TRANS — Transformer
TXV
— Thermostatic Expansion Valve
Factory Line Voltage Wiring
Factory Low Voltage Wiring
NOTES:
must be “Class 1” and voltage rating equal to or greater than unit
supply voltage.
6. 24-v alarm signal shown. For dry alarm contact, cut JW1 jumper
and dry contact will be available between AL1 and AL2.
7. Transformer secondary ground via Complete C board standoffs
and screws to control box. (Ground available from top two stand-
offs as shown.)
8. Suffix 1 designates association with lead compressor. Suffix 2
with lag compressor.
9. For dual point power (DPP) option, blower wire will connect to
other PBD.
1. Compressor and blower motor thermally protected internally.
2. All wiring to the unit must comply with NEC (National Electrical
Code, U.S.A.) and local codes.
3. 380/420-v transformers will be connected for 380-v operation. For
420-v operation, disconnect VIO lead at L1, and attach BRN lead
to L1. Close open end of VIO lead.
4. FPI thermistor provides freeze protection for WATER. When using
ANTIFREEZE solutions, cut JW3 jumper.
5. Typical heat pump thermostat wiring shown. Refer to thermostat
installation instructions for wiring to the unit. Thermostat wiring
Fig. 12 — 50HQP072-120 Units — Typical Control Wiring with Complete C Control
11
12
COMPLETE
C
CONTROL
PREMIER
LINK
PWR
LEGEND
CR — Control Relay
LWT — Leaving Water Temperature Sensor
SAT — Supply Air Temperature Sensor
SPT — Space Temperature Sensor
Y
HS1/EXH/RVS
W
CR
CR
NOTE: Reversing valve is on in Cooling
mode.
O
G
R
C
CMP1
FAN
AL1
AL2
A
J5
J6
J4
L
W
T
S
P
T
S
A
T
Fig. 14 — Premierlink™ Controller Applications Wiring with Complete C Control
PREMIER
LINK
PWR
DELUXE
D
CONTROL
Y1
Y2
HS2
HS1
W1
O/W2
G
LEGEND
CMP2
CMP1
FAN
LWT — Leaving Water Temperature Sensor
SAT — Supply Air Temperature Sensor
SPT — Space Temperature Sensor
NOTE: Reversing valve is on in Cooling
mode.
R
C
AL1
J5
J6
J4
L
W
T
S
P
T
S
A
T
Fig. 15 — Premierlink Controller Applications Wiring with Deluxe D Control
13
Table 3A — Electrical Data — 50HQP072-120 Standard Units
COMPRESSOR
RLA
FAN
MOTOR
FLA
TOTAL
UNIT
FLA
MIN
CIRCUIT
AMP
UNIT
50HQP
VOLTAGE
CODE
MIN/MAX BLOWER
MAX
FUSE
VOLTAGE
VOLTAGE
OPTION
QTY
LRA
072
096
120
9
9
9
380/420-3-50
380/420-3-50
380/420-3-50
360/440
360/440
360/440
A,B,C
A,B,C
A,B,C
2
2
2
5.4
6.1
7.8
38.0
43.0
51.5
1.8
3.4
4.9
12.6
15.6
20.5
13.9
17.1
22.5
15
20
30
Table 3B — Electrical Data — 50HQP072-120 Dual Point Power Units
EMERGENCY
POWER SUPPLY
COMPRESSOR
UNIT VOLTAGE
MIN/MAX BLOWER
VOLTAGE OPTION
VOLTAGE
Total
Comp
FLA
Comp
Max
Fuse
Fan
Motor
FLA
FAN
50HQP
CODE
Comp
MCA
Fan
MCA
QTY
RLA
LRA
MAX
FUSE
072
096
120
9
9
9
380/420-3-50 360/440
380/420-3-50 360/440
380/420-3-50 360/440
A,B,C
A,B,C
A,B,C
2
2
2
5.4
6.1
7.8
38.0
43.0
51.5
10.8
12.2
15.6
12.2
13.7
17.6
15
15
25
1.8
3.4
4.9
2.3
4.3
6.1
15
15
15
LEGEND
FLA
—
Full Load Amps
HACR
LRA
MCA
RLA
—
—
—
—
Heating, Air Conditioning, and Refrigeration
Locked Rotor Amps
Minimum Circuit Amps
Rated Load Amps
*Time-delay fuse or HACR circuit breaker.
Table 4 — Low Voltage VA Ratings
COMPONENTS IN UNIT
VA
Typical Blower Contactor
6 - 9
Typical Reversing Valve Solenoid (2)
30A Compressor Contactor (2)
Complete C Board (2)
8 - 12
12 - 18
10 - 18
16 - 24
Deluxe D Board (2)
Remaining VA for Accessories*
Units with Complete C
Units with Deluxe D
18 - 39
12 - 33
Complete C 1
Complete C 2
* Standard transformer is 75 VA.
POWER
BLOCK
Fig. 17 — Line Voltage Wiring
NOTE: Low voltage connector may be removed for easy installation.
Fig. 16 — Low Voltage Field Wiring
14
Step 10 — Install Field Control Wiring
THERMOSTAT CONNECTIONS — The thermostat should
be wired directly to the Aquazone™ control board. See
Fig. 18 and 19.
TERMINAL STRIP P2
C
The thermostat should be located on an interior wall in a
larger room, away from supply duct drafts. DO NOT locate the
thermostat in areas subject to sunlight, drafts or on external
walls. The wire access hole behind the thermostat may in cer-
tain cases need to be sealed to prevent erroneous temperature
measurement.
TYPICAL
WATER
VALVE
24 VAC
A
Fig. 19 — Typical Aquazone Accessory Wiring
(Control D Shown)
Position the thermostat back plate against the wall so that it
appears level and so the thermostat wires protrude through the
middle of the back plate. Mark the position of the back plate
3
WATER SOLENOID VALVES — Water solenoid valves may
be used on variable flow systems and ground water installa-
tions. A typical well water control valve wiring which can
limit waste water in a lockout condition is shown in Fig. 18. A
slow closing valve may be required to prevent water hammer.
When using a slow closing valve, special wiring conditions
need to be considered. The valve takes approximately 60 sec-
onds to open (very little water will flow before 45 seconds) and
it activates the compressor only after the valve is completely
opened by closing its end switch. When wired as shown, the
valve will have the following operating characteristics:
mounting holes and drill holes with a /16-in. bit. Install sup-
plied anchors and secure plate to the wall. Thermostat wire
must be 18 AWG (American Wire Gage) wire. Wire the appro-
priate thermostat as shown in Fig. 20 and 21 to the low voltage
terminal strip on the Complete C or Deluxe D control board.
Most heat pump thermostats will work with a Carrier unit,
provided the thermostat has the correct number of heating and
cooling stages.
WATER FREEZE PROTECTION — The Aquazone control
allows the field selection of source fluid freeze protection
points through jumpers. The factory setting of jumper JW3
(FP1) is set for water at –1.1 C. In earth loop applications,
jumper JW3 should be clipped to change the setting to –12.2 C
when using antifreeze in colder earth loop applications. See
Fig. 18.
1. Remain open during a lockout.
2. Draw approximately 25 to 35 VA through the “Y” signal
of the thermostat.
IMPORTANT: The use of a slow-closing water solenoid
valve can overheat the anticipators of electromechanical
thermostats. Only use relay based electronic thermostats.
AIR COIL FREEZE PROTECTION — The air coil freeze
protection jumper JW2 (FP2) is factory set for –1.1 C and
should not need adjusting.
ACCESSORY CONNECTIONS — Terminal labeled A on
the control is provided to control accessory devices such as
water valves, electronic air cleaners, humidifiers, etc. This sig-
nal operates with the compressor terminal. See Fig. 19. Refer
to the specific unit wiring schematic for details.
NOTE: The A terminal should only be used with 24 volt
signals — not line voltage signals.
CompleteC 1 CompleteC 2
THERMOSTAT
Y
Y
Y1
Y2
O
Compressor-Stage 1
Compressor-Stage 2
Reversing Valve
Fan
O
G
R
C
O
G
R
G
24Vac Hot
R
C
24Vac Com
C
AL
AL
AL
Fig. 20 — Thermostat Wiring to Complete C Board
Deluxe D 1
Deluxe D 2
THERMOSTAT
COM 2
COM 2
Y
Y1
Y1
Y2
O
Compressor-Stage 1
Y2
O
G
R
Compressor-Stage 2
Reversing Valve
Fan
O
G
R
G
24Vac Hot
R
C
C
24Vac Com
C
AL
AL1
AL1
AQUAZONE CONTROL (Complete C Control Shown)
Fig. 18 — Typical Aquazone™ Control Board
Jumper Locations
Fig. 21 — Thermostat Wiring to Deluxe D Board
15
To adjust sheave position, follow the procedure outlined
below:
1. Loosen belt tension and remove belt.
2. Loosen set screw on fan motor.
PRE-START-UP
System Checkout — When the installation is complete,
follow the system checkout procedure outlined below before
starting up the system. Be sure:
3. Open sheave to desired position.
4. Retighten set screw and replace belt.
NOTE: Set belt tension as outlined below.
BELT TENSION ADJUSTMENT — An overly loose belt
will, upon starting motor, produce a slippage “squeal” and
cause premature belt failure and or intermittent airflow. An
overly tight belt can cause premature motor or blower bear-
ing failure. To adjust the belt tension, follow the procedure
outlined below:
1. Remove belt from motor sheave.
2. Lift motor assembly.
3. Loosen the 5/16-in. hex nuts on the grommet motor adjust-
ment bolts (2 per bolt). To increase the belt tension loosen
the top hex nut. To decrease the belt tension loosen the
bottom hex nut.
1. Voltage is within the utilization range specifications of the
unit compressor and fan motor and voltage is balanced
for 3-phase units.
2. Fuses, breakers and wire are correct size.
3. Low voltage wiring is complete.
4. Piping and system flushing is complete.
5. Air is purged from closed loop system.
6. System is balanced as required. Monitor if necessary.
7. Isolation valves are open.
8. Water control valves or loop pumps are wired.
9. Condensate line is open and correctly pitched.
10. Transformer switched to lower voltage tap if necessary.
11. Blower rotates freely — shipping support is removed.
12. Blower speed is on correct setting.
13. Air filter is clean and in position.
14. Service/access panels are in place.
15. Return-air temperature is 4.4 to 26.7 C for heating and
10.0 to 43.3 C for cooling.
16. Air coil is clean.
4. Turn the bolts by hand to the desired position then tighten
the 5/16-in. hex nuts (2 per bolt).
5. Lower the motor assembly.
6. Install the belt.
7. The belt tension can be adjusted by using one of the fol-
lowing methods:
17. Control field selected settings are correct.
AIR COIL — To obtain maximum performance, the air coil
should be cleaned before starting the unit. A ten percent
solution of dishwasher detergent and water is recommended
for both sides of the coil. Rinse thoroughly with water.
a. Tighten until belt deflects approximately 13 mm
with very firm finger pressure.
b. Grasp belt midway between two pulleys and twist
for a 90-degreerotation.
Airflow and External Static Pressure — The
50HQP units are available with standard, low, and high-static
factory-installed options. These options will substitute a differ-
ent blower drive sheave for each static range. In addition, cer-
tain static ranges may require the optional large fan motor.
NOTE: Adjusting less than 90degreeswill over-
tighten the belt and adjusting more than 90degrees
will loosen belt.
c. Set proper belt tension to 32 to 36 kg.
NOTE: The motor position should not need adjustment. Motor
sheave position is at mid position of each sheave. For example,
the motor sheave is 2.5 turns open on a 5-turn sheave. The belt
tension adjustment can also be accomplished by turning the
5/16-in. hex nuts to the desired position.
SHEAVE ADJUSTMENT — The 50HQP units are supplied
with a variable sheave drive on the fan motor to adjust for dif-
fering airflows at various ESP (external static pressure) condi-
tions. See Tables 5-7 for unit airflows. When fully closed, the
sheave will produce the highest static capability (higher rpm).
NOTE: Available airflows for all units are shown in
Tables 5-7.
16
Table 5 — Blower Data — 50HQP072
EXTERNAL STATIC PRESSURE (Pa)
AIRFLOW
(l/s)
0
—
25
—
50
0.09
B
75
0.12
A
100
0.14
A
125
0.17
A
150
0.19
A
175
0.21
A
200
0.24
C
225
0.25
C
250
0.27
C
275
0.29
C
300
0.31
C
325
0.32
C
350
0.34
C
375
0.35
C
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
—
—
614
661
—
—
505
3
563
5
615
3.5
0.19
A
655
3
695
2
730
1
765
5
790
4.5
0.30
C
815
4
840
3.5
0.34
C
870
2.5
0.36
C
890
2.5
0.38
C
910
2
925
1.5
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
0.12
B
0.14
A
0.17
A
0.22
A
0.24
C
0.26
C
0.29
C
0.33
C
0.40
C
—
—
526
2
578
4.5
0.17
A
635
3
675
2.5
0.22
A
715
1.5
0.25
A
755
5
785
4.5
0.29
C
815
4
840
3.5
0.34
C
870
3
890
2
910
2
930
1.5
0.43
C
950
1
—
0.12
B
0.14
B
0.19
A
0.27
C
0.32
C
0.36
C
0.38
C
0.41
C
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
708
500
3
547
1.5
0.17
B
604
4
650
3
695
2
735
1
775
4.5
0.29
C
805
4
835
3.5
0.34
C
865
3
890
2.5
0.39
C
915
2
940
1.5
0.44
C
960
1
0.14
B
0.19
A
0.22
A
0.25
A
0.27
A
0.32
C
0.37
C
0.41
C
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
755
510
2.5
0.16
B
568
1
620
3.5
0.22
A
665
2.5
0.24
A
710
1.5
0.27
A
750
1
785
4.5
0.32
C
820
3.5
0.34
C
855
3
885
2.5
0.39
C
910
2
935
1.5
0.44
C
960
1
0.19
A
0.29
C
0.36
C
0.42
C
—
—
802
531
2
583
4.5
0.18
B
635
3.5
0.21
A
680
2.5
0.24
A
720
1.5
0.26
A
765
5
800
4
835
3.5
0.34
C
870
2.5
0.36
C
900
2
925
1.5
0.42
C
950
1
—
—
0.15
B
0.29
A
0.31
C
0.39
C
0.45
C
—
—
850
500
3
547
1.5
0.21
B
599
4
645
3
690
2
735
1
775
5
815
4
850
3
885
2.5
0.46
C
910
2
940
1.5
0.52
C
—
—
0.18
B
0.23
A
0.27
A
0.30
A
0.33
A
0.36
C
0.40
C
0.43
C
0.49
C
—
—
897
510
2.5
0.21
B
557
1.5
0.23
B
604
4
655
3
695
2
740
1
780
4.5
0.41
C
820
3.5
0.44
C
855
3
890
2
920
1.5
0.54
C
950
1
—
—
0.26
A
0.29
A
0.33
A
0.37
C
0.48
C
0.50
C
0.56
C
—
—
944
521
2.5
0.25
B
568
1
615
3.5
0.32
A
660
2.5
0.34
A
705
1.5
0.37
A
750
5.5
0.40
C
785
4.5
0.44
C
825
3.5
0.48
C
865
2.5
0.52
C
895
2
930
1.5
0.58
C
960
1
—
—
0.28
A
0.55
C
—
—
—
—
991
536
2
583
4.5
0.30
A
630
3.5
0.34
A
670
2.5
0.37
A
715
1.5
0.41
A
755
5
795
4
835
3.5
0.52
C
875
2.5
0.56
C
905
2
940
1
—
—
—
—
0.28
A
0.45
C
0.48
C
0.59
C
0.62
C
—
—
—
—
1038
1086
1133
1180
557
5
599
4
645
3
685
2
730
1
770
5
810
4
850
3
885
2.5
0.60
C
915
1.5
0.63
C
950
1
—
—
—
—
0.32
A
0.35
A
0.38
A
0.42
A
0.45
A
0.48
C
0.52
C
0.56
C
0.67
C
—
—
—
—
573
4.5
0.36
A
620
3.5
0.39
A
660
3
705
1.5
0.46
A
745
1
785
4.5
0.54
C
820
3.5
0.58
C
860
3
895
2
925
1.5
0.69
C
960
1
—
—
—
—
0.43
A
0.49
C
0.62
C
0.65
C
—
—
—
—
—
—
609
4
645
3
690
2.5
0.46
A
730
1.5
0.49
A
765
5
805
4
845
3
880
2.5
0.66
C
910
2
945
1
—
—
—
Turns Open
BkW
Sheave/Mtr
RPM
—
—
—
0.39
A
0.42
A
0.54
C
0.58
C
0.62
C
0.70
C
0.73
C
—
—
—
—
—
—
620
3.5
660
3
700
2
740
1
780
4.5
815
4
850
3
885
2.5
920
1.5
950
1
—
—
—
Turns Open
—
—
—
LEGEND
Operation Not Recommended
BkW — Brake Kilowatts
ESP External Static Pressure
NOTES:
1. A = Standard Rpm/Standard Motor, B = Low Rpm/Standard Motor, C =
High Rpm/Standard Motor.
—
—
2. Unit factory shipped with standard static sheave and drive at 2.5 turns
open. Other speed require field selection.
3. For applications requiring higher static pressures, contact your local rep-
resentative. Performance data does not include drive losses and is based
on sea level conditions.
4. All airflow is rated at lowest voltage if unit is dual voltage rated, i.e., 380V
for 380/420V units.
5. Airflow in l/s with wet coil and clean filter.
—
RPM — Revolutions Per Minute
A
B
C
—
—
—
Units with Standard Rpm/Standard Motor Option
Units with Low Rpm/Standard Motor Option
Units with High Rpm/Standard Motor Option
a50-8544
17
Table 6 — Blower Data — 50HQP096
EXTERNAL STATIC PRESSURE (Pa)
AIRFLOW
(l/s)
0
—
25
0.15
B
50
0.18
B
75
0.21
B
100
0.24
A
125
0.27
A
150
0.30
A
175
0.32
A
200
0.34
A
225
0.36
A
250
0.39
C
275
0.42
C
300
0.46
C
325
0.49
C
350
0.52
C
375
0.55
C
BkW
Sheave/Mtr
RPM
—
850
897
—
500
4.5
0.21
B
552
3
604
1.5
0.28
A
655
5.5
0.31
A
700
4.5
0.34
A
745
3.5
0.38
A
780
2.5
0.41
A
820
2
855
1
890
4
915
3.5
0.53
C
945
3
970
2.5
0.58
C
995
2
1020
1.5
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
Turns Open
BkW
—
0.19
B
0.24
A
0.44
A
0.47
C
0.50
C
0.55
C
0.61
C
Sheave/Mtr
RPM
521
4
573
2.5
0.22
B
625
6
670
5
710
4
755
3
795
2.5
0.39
A
830
1.5
0.42
A
870
1
900
3.5
0.49
C
930
3
960
2.5
0.55
C
990
2
1015
1.5
0.60
C
1040
1
Turns Open
BkW
0.20
B
0.25
B
0.28
A
0.32
A
0.36
A
0.46
A
0.52
C
0.58
C
0.63
C
Sheave/Mtr
RPM
944
500
4.5
0.24
B
542
3.5
0.27
B
594
2
640
5.5
0.33
A
685
4.5
0.36
A
730
3.5
0.39
A
770
3
805
2
845
1
880
4
915
3.5
0.57
C
945
2.5
0.60
C
975
2
1005
1.5
0.66
C
1030
1
Turns Open
BkW
0.30
B
0.43
A
0.47
A
0.51
A
0.54
C
0.63
C
0.69
C
Sheave/Mtr
RPM
991
516
4
563
3
615
1.5
0.32
A
655
5.5
0.36
A
700
4.5
0.40
A
740
3.5
0.43
A
780
2.5
0.47
A
820
2
860
1
895
4
925
3
960
2.5
0.64
C
990
2
1020
1
1045
1
Turns Open
BkW
0.26
B
0.29
B
0.51
A
0.54
C
0.58
C
0.61
C
0.67
C
0.71
C
—
Sheave/Mtr
RPM
—
1038
1086
1133
1180
1227
1274
1322
1369
1416
1463
1510
536
3.5
0.30
B
583
2.5
0.34
B
630
6
670
5
715
4
755
3
795
2.5
0.51
A
835
1.5
0.55
A
870
4
905
3.5
0.62
C
935
3
970
2
1000
1.5
0.73
C
1030
1
—
Turns Open
BkW
—
0.37
A
0.40
A
0.43
A
0.47
A
0.59
C
0.66
C
0.69
C
0.77
C
—
Sheave/Mtr
RPM
—
557
3
604
2
650
5.5
0.41
A
690
4.5
0.44
A
730
3.5
0.47
A
770
3
810
2
845
1
885
4
915
3.5
0.67
C
950
2.5
0.71
C
980
2
1010
1.5
0.78
C
1040
1
—
Turns Open
BkW
—
0.34
B
0.37
A
0.51
A
0.56
A
0.60
A
0.64
C
0.74
C
—
—
Sheave/Mtr
RPM
—
—
583
2.5
0.38
B
625
6
665
5
705
4
745
3.5
0.52
A
785
2.5
0.56
A
825
1.5
0.61
A
860
1
895
4
925
3
960
2.5
0.75
C
990
2
1020
1
—
—
Turns Open
BkW
—
—
0.41
A
0.44
A
0.48
A
0.65
C
0.69
C
0.72
C
0.79
C
0.83
C
—
—
Sheave/Mtr
RPM
—
—
604
2
645
5.5
0.45
A
685
4.5
0.48
A
725
4
765
3
800
2
835
1.5
0.64
A
875
4
905
3.5
0.72
C
940
3
970
2
1005
1.5
0.85
C
1030
1
—
—
Turns Open
BkW
—
—
0.41
A
0.51
A
0.55
A
0.60
A
0.69
C
0.76
C
0.80
C
—
—
—
Sheave/Mtr
RPM
—
—
—
625
6
665
5
700
4.5
0.52
A
740
3.5
0.56
A
775
3
815
2
850
1
885
4
915
3.5
0.77
C
950
2.5
0.81
C
985
2
1015
1.5
0.90
C
—
—
—
Turns Open
BkW
—
—
—
0.45
A
0.49
A
0.60
A
0.64
A
0.68
A
0.73
C
0.85
C
—
—
—
Sheave/Mtr
RPM
—
—
—
645
5.5
0.49
A
685
4.5
0.53
A
720
4
760
3
795
2.5
0.65
A
830
1.5
0.69
A
865
1
900
3.5
0.78
C
930
3
960
2.5
0.86
C
995
1.5
0.91
C
1025
1
—
—
—
Turns Open
BkW
—
—
—
0.57
A
0.61
A
0.74
C
0.82
C
0.96
C
—
—
—
Sheave/Mtr
RPM
—
—
—
665
5
705
4
745
3.5
0.61
A
780
2.5
0.65
A
810
2
845
1
880
4
910
3.5
0.82
C
945
2.5
0.87
C
975
2
1005
1.5
0.96
C
1035
1
—
—
—
Turns Open
BkW
—
—
—
0.53
A
0.57
A
0.69
A
0.73
A
0.77
C
0.91
C
1.02
C
—
—
—
Sheave/Mtr
RPM
—
—
—
685
4.5
0.58
A
720
4
760
3
795
2.5
0.71
A
825
1.5
0.75
A
860
1
890
4
920
3
955
2.5
0.93
C
985
2
1015
1.5
1.03
C
1045
1
—
—
—
Turns Open
BkW
—
—
—
0.62
A
0.67
A
0.79
C
0.84
C
0.88
C
0.97
C
—
—
—
—
Sheave/Mtr
RPM
—
—
—
—
700
4.5
0.64
A
735
3.5
0.68
A
775
2.5
0.72
A
810
2
845
1
875
4
910
3.5
0.90
C
940
3
970
2
1000
1.5
1.07
C
1030
1
—
—
—
—
Turns Open
BkW
—
—
—
—
0.76
A
0.80
A
0.85
C
0.97
C
1.02
C
1.12
C
—
—
—
—
Sheave/Mtr
RPM
—
—
—
—
720
4
755
3
790
2.5
0.80
A
825
1.5
0.85
A
860
1
890
4
920
3
955
2.5
1.03
C
985
2
1015
1.5
1.13
C
1040
1
—
—
—
—
Turns Open
BkW
—
—
—
—
0.70
A
0.75
A
0.90
C
0.94
C
0.99
C
1.08
C
—
—
—
—
—
Sheave/Mtr
RPM
—
—
—
—
—
740
3.5
775
2.5
810
2
840
1.5
875
4
905
3.5
935
3
965
2.5
995
1.5
1025
1
—
—
—
—
—
Turns Open
—
—
—
—
—
LEGEND
Operation Not Recommended
BkW — Brake Kilowatts
ESP External Static Pressure
NOTES:
1. A = Standard Rpm/Standard Motor, B = Low Rpm/Standard Motor, C =
High Rpm/Standard Motor.
—
—
2. Unit factory shipped with standard static sheave and drive at 2.5 turns
open. Other speed require field selection.
3. For applications requiring higher static pressures, contact your local rep-
resentative. Performance data does not include drive losses and is based
on sea level conditions.
4. All airflow is rated at lowest voltage if unit is dual voltage rated, i.e., 380V
for 380/420V units.
5. Airflow in l/s with wet coil and clean filter.
—
RPM — Revolutions Per Minute
A
B
C
—
—
—
Units with Standard Static/Standard Motor Option
Units with Low Static/Standard Motor Option
Units with High Static/Standard Motor Option
18
Table 7 — Blower Data — 50HQP120
EXTERNAL STATIC PRESSURE (Pa)
AIRFLOW
(l/s)
0
—
25
0.29
B
50
0.31
B
75
0.35
B
100
0.39
B
125
0.42
A
150
0.46
A
175
0.50
A
200
0.54
A
225
0.57
A
250
0.60
A
275
0.63
C
300
0.67
C
325
0.70
C
350
0.73
C
375
0.76
C
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
—
1038
1086
1133
1180
1227
1274
1322
1369
1416
1463
1510
1558
—
573
4.5
0.33
B
620
3.5
0.37
B
665
2.5
0.40
B
705
1.5
0.43
A
745
5.5
0.46
A
785
4.5
0.50
A
825
3.5
0.54
A
865
3
900
2
930
1.5
0.65
A
960
3.5
0.68
C
995
3
1020
2.5
0.76
C
1050
2
1075
1.5
0.85
C
—
0.30
B
0.58
A
0.61
A
0.72
C
0.80
C
547
5
594
4
640
3
680
2
720
6
760
5
800
4
840
3.5
0.59
A
875
2.5
0.63
A
910
2
940
1.5
0.70
A
975
3.5
0.73
C
1005
3
1035
2
1060
1.5
0.86
C
1090
1
0.34
B
0.37
B
0.40
B
0.43
B
0.47
A
0.50
A
0.55
A
0.66
A
0.77
C
0.82
C
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
573
4.5
0.37
B
615
3.5
0.40
B
660
2.5
0.44
B
700
2
740
5.5
0.51
A
775
4.5
0.55
A
815
4
855
3
890
2.5
0.68
A
920
1.5
0.71
A
955
1
985
3
1015
2.5
0.82
C
1045
2
1075
1.5
0.91
C
0.47
A
0.60
A
0.64
A
0.75
C
0.78
C
0.87
C
594
4
635
3
675
2.5
0.47
B
715
6
755
5
790
4.5
0.59
A
830
3.5
0.63
A
865
3
900
2
930
1.5
0.75
A
965
3.5
0.79
C
995
3
1025
2.5
0.88
C
1055
1.5
0.92
C
1085
1
0.40
B
0.44
B
0.51
A
0.55
A
0.67
A
0.72
A
0.83
C
0.96
C
615
3.5
0.44
B
655
3
690
2
730
5.5
0.55
A
770
5
805
4
840
3.5
0.67
A
875
2.5
0.71
A
910
2
940
1
975
3.5
0.84
C
1005
3
1035
2
1065
1.5
0.97
C
1095
1
0.47
B
0.51
B
0.59
A
0.63
A
0.75
A
0.79
A
0.88
C
0.93
C
—
—
635
3
670
2.5
0.51
B
710
1.5
0.55
A
750
5
785
4.5
0.64
A
820
3.5
0.67
A
855
3
885
2.5
0.76
A
920
1.5
0.80
A
950
1
985
3
1015
2.5
0.94
C
1045
2
1075
1.5
1.05
C
—
—
0.47
B
0.59
A
0.72
A
0.84
C
0.89
C
1.00
C
—
—
650
3
690
2
725
6
765
5
800
4
830
3.5
0.71
A
865
3
900
2
930
1.5
0.85
A
960
3.5
0.89
C
995
3
1025
2.5
0.99
C
1055
1.5
1.04
C
1085
1
—
—
0.52
B
0.55
B
0.59
A
0.63
A
0.67
A
0.75
A
0.80
A
0.94
C
1.10
C
—
—
670
2.5
0.57
B
705
1.5
0.60
A
745
5.5
0.65
A
780
4.5
0.68
A
810
4
845
3
875
2.5
0.82
A
910
2
940
1
970
3.5
0.95
C
1000
3
1030
2
1060
1.5
1.11
C
1090
1
—
—
0.73
A
0.77
A
0.86
A
0.91
A
1.00
C
1.05
C
—
—
—
—
685
2
720
6
760
5
790
4.5
0.75
A
825
3.5
0.79
A
860
3
895
2
925
1.5
0.94
A
955
1
985
3
1015
2.5
1.09
C
1045
2
1075
1.5
1.20
C
—
—
—
—
0.61
B
0.66
A
0.70
A
0.82
A
0.89
A
0.99
C
1.05
C
1.15
C
—
—
—
—
700
Open
0.68
A
735
2
775
5.5
0.77
A
810
4.5
0.82
A
845
4
875
3
910
2.5
0.96
A
940
2
970
1.5
1.05
C
1000
3.5
1.10
C
1025
3
1055
2.5
1.20
C
1085
1.5
1.26
C
—
—
—
—
0.73
A
0.88
A
0.92
A
1.01
A
1.16
C
—
—
—
—
725
6
760
5
790
4.5
0.83
A
825
3.5
0.88
A
860
3
890
2
920
1.5
1.02
A
950
1
980
3.5
1.11
C
1010
2.5
1.16
C
1040
2
1065
1.5
1.26
C
1095
1
—
—
—
—
0.74
A
0.79
A
0.94
A
0.98
A
1.07
C
1.21
C
—
—
—
—
—
—
740
5.5
775
4.5
805
4
840
3.5
875
2.5
905
2
935
1.5
965
3.5
995
3
1020
2.5
1050
2
1075
1.5
—
—
—
Turns Open
—
—
—
LEGEND
Operation Not Recommended
BkW — Brake Kilowatts
ESP External Static Pressure
NOTES:
1. A = Standard Rpm/Standard Motor, B = Low Rpm/Standard Motor, C =
High Rpm/Standard Motor.
—
—
2. Unit factory shipped with standard static sheave and drive at 2.5 turns
open. Other speed require field selection.
3. For applications requiring higher static pressures, contact your local rep-
resentative. Performance data does not include drive losses and is based
on sea level conditions.
4. All airflow is rated at lowest voltage if unit is dual voltage rated, i.e., 380V
for 380/420V units.
5. Airflow in l/s with wet coil and clean filter.
—
RPM — Revolutions Per Minute
A
B
C
—
—
—
Units with Standard Static/Standard Motor Option
Units with Low Static/Standard Motor Option
Units with High Static/Standard Motor Option
19
Table 7 — Blower Data — 50HQP120 (cont)
EXTERNAL STATIC PRESSURE (Pa)
AIRFLOW
(l/s)
0
0.79
A
25
0.85
A
50
0.89
A
75
0.94
A
100
0.99
A
125
1.04
A
150
1.08
A
175
1.12
C
200
1.17
C
225
1.23
C
250
1.29
C
275
1.35
C
300
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
325
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
350
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
375
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
Turns Open
BkW
Sheave/Mtr
RPM
1605
1652
1699
1746
1794
1841
1888
755
5
790
4.5
0.91
A
820
3.5
0.96
A
855
3
890
2
920
1.5
1.11
A
945
1
975
3.5
1.20
C
1005
3
1035
2
1060
1.5
1.34
C
1090
1
0.87
A
1.02
A
1.06
A
1.15
C
1.24
C
1.29
C
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
780
4.5
0.94
A
810
4
845
3
880
2.5
1.09
A
910
2
940
1
970
3.5
1.25
C
1000
3
1025
2.5
1.35
C
1050
2
1080
1
0.99
A
1.04
A
1.15
A
1.20
C
1.30
C
1.40
C
1.45
C
805
4
835
3.5
1.05
A
870
2.5
1.10
A
900
2
930
1.5
1.21
A
960
3.5
1.26
C
990
3
1015
2.5
1.37
C
1045
2
1070
1.5
1.49
C
1100
1
1.01
A
1.16
A
1.32
C
1.43
C
—
—
825
3.5
1.07
A
855
3
885
2.5
1.17
A
915
1.5
1.22
A
945
1
975
3.5
1.33
C
1005
3
1030
2
1060
1.5
1.51
C
1085
1
—
—
1.11
A
1.27
C
1.38
C
1.45
C
1.57
C
—
—
840
3.5
1.17
A
870
2.5
1.21
A
900
2
930
1.5
1.32
A
960
3.5
1.38
C
990
3
1015
2.5
1.49
C
1045
2
1070
1.5
1.62
C
1095
1
—
—
1.27
A
1.43
C
1.55
C
—
—
—
—
860
3
885
2.5
1.29
A
915
1.5
1.35
A
945
1
975
3.5
1.48
C
1005
3
1030
2
1055
1.5
1.66
C
1085
1
—
—
—
—
1.23
A
1.41
C
1.53
C
1.60
C
1.72
C
—
—
—
—
875
2.5
900
2
930
1.5
960
3.5
990
3
1015
2.5
1045
2
1070
1.5
1095
1
—
—
Turns Open
—
—
LEGEND
Operation Not Recommended
BkW — Brake Kilowatts
ESP External Static Pressure
NOTES:
1. A = Standard Rpm/Standard Motor, B = Low Rpm/Standard Motor, C =
High Rpm/Standard Motor.
—
—
2. Unit factory shipped with standard static sheave and drive at 2.5 turns
open. Other speed require field selection.
3. For applications requiring higher static pressures, contact your local rep-
resentative. Performance data does not include drive losses and is based
on sea level conditions.
4. All airflow is rated at lowest voltage if unit is dual voltage rated, i.e., 380V
for 380/420V units.
5. Airflow in l/s with wet coil and clean filter.
—
RPM — Revolutions Per Minute
A
B
C
—
—
—
Units with Standard Static/Standard Motor Option
Units with Low Static/Standard Motor Option
Units with High Static/Standard Motor Option
FIELD SELECTABLE INPUTS
Complete C Control DIP Switches — The Com-
plete C Control has 1 DIP switch block with five switches. See
Fig. 12.
PERFORMANCE MONITOR (PM) — DIP switch 1 will
enable or disable this feature. To enable the PM, set the switch
to ON. To disable the PM, set the switch to OFF.
STAGE 2 — DIP switch 2 will enable or disable compressor
delay. Set DIP switch to OFF for stage 2 in which the compres-
sor will have a 3-second delay before energizing.
NOTE: The alarm relay will not cycle during Test mode if
switch is set to OFF, stage 2.
DIP SWITCH 3 — not used.
DIP SWITCH 4 — not used.
DIP SWITCH 5 — DIP switch 5 is used to initiate 1 or 3 tries
for the FP1 fault. If water freeze protection for the water coil
then DIP switch 5 can be set to lockout on the FP1 fault after
one try.
Jumpers and DIP (dual in-line package) switches on the
control board are used to customize unit operation and can be
configured in the field.
IMPORTANT: Jumpers and DIP switches should only be
clipped when power to control board has been turned off.
Complete C Control Jumper Settings (See
Fig. 12)
WATER COIL FREEZE PROTECTION (FP1) LIMIT
SETTING — Select jumper 3, (JW3-FP1 Low Temp) to
choose FP1 limit of –12.2 C or –1.1 C. To select –1.1 C as the
limit, DO NOT clip the jumper. To select –12.2 C as the limit,
clip the jumper.
AIR COIL FREEZE PROTECTION (FP2) LIMIT SET-
TING — Select jumper 2 (JW2-FP2 Low Temp) to choose
FP2 limit of –12.2 C or –1.1 C. To select –1.1 C as the limit,
DO NOT clip the jumper. To select –12.2 C as the limit, clip
the jumper.
Deluxe D Control Jumper Settings (See
Fig. 13)
ALARM RELAY SETTING — Select jumper 1 (JW1-AL2
Dry) for connecting alarm relay terminal (AL2) to 24 vac (R) or
to remain as a dry contact (no connection). To connect AL2 to
R, do not clip the jumper. To set as dry contact, clip the jumper.
WATER COIL FREEZE PROTECTION (FP1) LIMIT
SETTING — Select jumper 3, (JW3-FP1 Low Temp) to
choose FP1 limit of –12.2 C or –1.1 C. To select –1.1 C as the
limit, DO NOT clip the jumper. To select –12.2 C as the limit,
clip the jumper.
20
AIR COIL FREEZE PROTECTION (FP2) LIMIT SET-
TING — Select jumper 2 (JW2-FP2 Low Temp) to choose
FP2 limit of –12.2 C or –1.1 C. To select –1.1 C as the limit,
DO NOT clip the jumper. To select –12.2 C as the limit, clip
the jumper.
ALARM RELAY SETTING — Select jumper 4 (JW4-AL2
Dry) for connecting alarm relay terminal (AL2) to 24 vac (R) or
to remain as a dry contact (no connection). To connect AL2 to
R, do not clip the jumper. To set as dry contact, clip the jumper.
compressor will not be used for heating when the FP1 is below
10.0 C and the compressor will operate in emergency heat
mode, staging on EH1 and EH2 to provide heat. If a thermal
switch is being used instead of the FP1 thermistor, only the
compressor will be used for heating mode when the FP1 termi-
nals are closed. If the FP1 terminals are open, the compressor is
not used and the control goes into emergency heat mode.
DIP SWITCH BLOCK 2 (S2) — This set of DIP switches is
used to configure accessory relay options. See Fig. 13.
LOW PRESSURE SETTING — The Deluxe D Control can
be configured for Low Pressure Setting (LP). Select jumper 1
(JW1-LP Norm Open) for choosing between low pressure in-
put normally opened or closed. To configure for normally
closed operation, do not clip the jumper. To configure for nor-
mally open operation, clip the jumper.
Switches 1 to 3 — These DIP switches provide selection of
Accessory 1 relay options. See Table 8 for DIP switch
combinations.
Switches 4 to 6 — These DIP switches provide selection
of Accessory 2 relay options. See Table 9 for DIP switch
combinations.
Auto Dehumidification Mode or High Fan Mode — Switch 7
provides selection of auto dehumidification fan mode or high
fan mode. In auto dehumidification fan mode the fan speed
relay will remain off during cooling stage 2 if terminal H is
active. In high fan mode, the fan enable and fan speed relays
will turn on when terminal H is active. Set the switch to ON for
auto dehumidification fan mode or to OFF for high fan mode.
Deluxe D Control DIP Switches — The Deluxe D
Control has 2 DIP switch blocks. Each DIP switch block has 8
switches and is labeled either S1 or S2 on the circuit board. See
Fig. 13.
DIP SWITCH BLOCK 1 (S1) — This set of switches offers
the following options for Deluxe D Control configuration:
Performance Monitor (PM) — Set switch 1 to enable or dis-
able performance monitor. To enable the PM, set the switch to
ON. To disable the PM, set the switch to OFF.
Compressor Relay Staging Operation — Switch 2 will enable
or disable compressor relay staging operation. The compressor
relay can be set to turn on with stage 1 or stage 2 call from the
thermostat. This setting is used with dual stage units (units with
2 compressors and 2 Deluxe D controls) or in master/slave ap-
plications. In master/slave applications, each compressor and
fan will stage according to its switch 2 setting. If switch is set to
stage 2, the compressor will have a 3-second delay before ener-
gizing during stage 2 demand.
Switch 8 — Not used.
Table 8 — DIP Switch Block S2 —
Accessory 1 Relay Options
DIP SWITCH POSITION
ACCESSORY 1
RELAY OPTIONS
1
2
3
Cycle with Fan
Digital NSB
Water Valve — Slow Opening
OAD
On
Off
On
On
On
On
Off
On
On
On
On
Off
LEGEND
NSB — Night Setback
OAD — Outside Air Damper
NOTE: If DIP switch is set for stage 2, the alarm relay will not
cycle during Test mode.
Heating/Cooling Thermostat Type — Switch 3 provides selec-
tion of thermostat type. Heat pump or heat/cool thermostats
can be selected. Select OFF for heat/cool thermostats. When in
heat/cool mode, Y1 is used for cooling stage 1, Y2 is used for
cooling stage 2, W1 is used for heating stage 1 and O/W2 is
used for heating stage 2. Select ON for heat pump applications.
In heat pump mode, Y1 used is for compressor stage 1, Y2 is
used for compressor stage 2, W1 is used for heating stage 3 or
emergency heat, and O/W2 is used for RV (heating or cooling)
depending upon switch 4 setting.
O/B Thermostat Type — Switch 4 provides selection for heat
pump O/B thermostats. O is cooling output. B is heating out-
put. Select ON for heat pumps with O output. Select OFF for
heat pumps with B output.
NOTE: All other DIP switch combinations are invalid.
Table 9 — DIP Switch Block S2 —
Accessory 2 Relay Options
DIP SWITCH POSITION
ACCESSORY 2
RELAY OPTIONS
4
5
6
Cycle with Fan
Digital NSB
Water Valve — Slow Opening
OAD
On
Off
On
On
On
On
Off
On
On
On
On
Off
LEGEND
NSB — Night Setback
OAD — Outside Air Damper
Dehumidification Fan Mode — Switch 5 provides selection
of normal or dehumidification fan mode. Select OFF for dehu-
midification mode. The fan speed relay will remain OFF dur-
ing cooling stage 2. Select ON for normal mode. The fan speed
relay will turn on during cooling stage 2 in normal mode.
NOTE: All other switch combinations are invalid.
Deluxe D Control Accessory Relay Configura-
tions — The following accessory relay settings are applica-
ble for both Deluxe D controls only:
Switch 6 — Not used.
Boilerless Operation — Switch 7 provides selection of boil-
erless operation and works in conjunction with switch 8. In
boilerless operation mode, only the compressor is used for
heating when FP1 is above the boilerless changeover tempera-
ture set by switch 8 below. Select ON for normal operation or
select OFF for boilerless operation.
Boilerless Changeover Temperature — Switch 8 on S1 pro-
vides selection of boilerless changeover temperature set point.
Select OFF for set point of 10.0 C or select ON for set point
of 4.4 C.
CYCLE WITH FAN — In this configuration, the relay will be
ON any time the Fan Enable relay is on.
CYCLE WITH COMPRESSOR — In this configuration, the
relay will be ON any time the Compressor relay is on.
DIGITAL NIGHT SET BACK (NSB) — In this configura-
tion, the relay will be ON if the NSB input is connected to
ground C.
NOTE: If there are no relays configured for digital NSB, then
the NSB and override (OVR) inputs are automatically config-
ured for mechanical operation.
If switch 8 is set for 10.0 C, then the compressor will be
used for heating as long as the FP1 is above 10.0 C. The
21
MECHANICAL NIGHT SET BACK — When NSB input is
connected to ground C, all thermostat inputs are ignored. A
thermostat set back heating call will then be connected to the
OVR input. If OVR input becomes active, then the Deluxe D
control will enter Night Low Limit (NLL) staged heating
mode. The NLL staged heating mode will then provide heating
during the NSB period.
WATER VALVE (SLOW OPENING) — If relay is config-
ured for Water Valve (slow opening), the relay will start 60 sec-
onds prior to starting compressor relay.
water temperature entering the heat pumps should be
between 10.0 and 43.3 C.
NOTE: Three factors determine the operating limits of a
unit: (1) entering-air temperature, (2) water temperature and
(3) ambient temperature. Whenever any of these factors are
at a minimum or maximum level, the other two factors must
be at a normal level to ensure proper unit operation. See
Table 10. Extreme variations in temperature and humidity and/
or corrosive water or air will adversely affect unit perfor-
mance, reliability, and service life.
OUTSIDE AIR DAMPER (OAD) — If relay is configured
for OAD, the relay will normally be ON any time the Fan
Enable relay is energized. The relay will not start for 30 min-
utes following a return to normal mode from NSB, when NSB
is no longer connected to ground C. After 30 minutes, the relay
will start if the Fan Enable is set to ON.
Table 10 — Operating Limits
AIR LIMITS
COOLING (C) HEATING (C)
Minimum Ambient Air db
Rated Ambient Air db
Maximum Ambient Air db
Minimum Entering Air db/wb
Rated Entering Air db/wb
Maximum Entering Air db/wb
WATER LIMITS
7
27
43
16/10
27/19
35/24
4
20
29
10
20
27
START-UP
CAUTION
Minimum Entering Water
Normal Entering Water
Maximum Entering Water
Normal Water Flow
–1
10 to 43
49
–6.7
–1 to 21
32
To avoid equipment damage, DO NOT leave system filled
in a building without heat during the winter unless anti-
freeze is added to system water. Condenser coils never
fully drain by themselves and will freeze unless winterized
with antifreeze.
1.6 to 3.2 L/m per kW
LEGEND
db
wb
—
—
Dry Bulb
Wet Bulb
Use the procedure outlined below to initiate proper unit
start-up.
NOTE: This equipment is designed for indoor installation only.
Scroll Compressor Rotation — It is important to be
certain compressor is rotating in the proper direction. To
determine whether or not compressor is rotating in the proper
direction:
1. Connect service gages to suction and discharge pressure
fittings.
WARNING
When the disconnect switch is closed, high voltage is pres-
ent in some areas of the electrical panel. Exercise caution
when working with the energized equipment.
2. Energize the compressor.
3. The suction pressure should drop and the discharge
pressure should rise, as is normal on any start-up.
If the suction pressure does not drop and the discharge
pressure does not rise to normal levels:
1. Turn off power to the unit. Install disconnect tag.
2. Reverse any two of the unit power leads.
3. Reapply power to the unit and verify pressures are correct.
Operating Limits
ENVIRONMENT — This equipment is designed for indoor
installation ONLY. Extreme variations in temperature, humidi-
ty and corrosive water or air will adversely affect the unit per-
formance, reliability and service life.
POWER SUPPLY — A voltage variation of ± 10% of name-
plate utilization voltage is acceptable.
UNIT STARTING CONDITIONS — All units can start and
operate in an ambient of 7.2 C with entering-air at 10.0/7.2 C
(db/wb), entering water at –1.1 C and with both air and water at
the flow rates used. All other conditions are the same as shown
in Table 10.
The suction and discharge pressure levels should now move
to their normal start-up levels.
When the compressor is rotating in the wrong direction, the
unit makes an elevated level of noise and does not provide
cooling.
NOTE: These operating conditions are not normal or continu-
ous operating conditions. It is assumed that such a start-up is
for the purpose of bringing the building space up to occupancy
temperature.
After a few minutes of reverse operation, the scroll com-
pressor internal overload protection will open, thus activating
the unit lockout. This requires a manual reset. To reset, turn the
thermostat on and then off.
NOTE: There is a 5-minute time delay before the compressor
will start.
Air Coil Cleaning — To obtain maximum performance,
the air coil should be cleaned before start-up. A 10% solution
of dishwasher detergent and water is recommended for both
sides of the coil. A thorough water rinse should follow. Ultra-
violet based anti-bacterial systems may damage e-coated air
coils.
Unit Start-Up in Cooling Mode
1. Adjust the unit thermostat to the warmest position.
Slowly reduce the thermostat position until the compres-
sor activates.
2. Check for cool air delivery at unit grille a few minutes
after the unit has begun to operate.
Start Up System
1. Restore power to system.
2. Turn thermostat fan position to ON. Blower should start.
3. Balance airflow at registers.
4. Adjust all valves to the full open position and turn on the
line power to all heat pump units.
5. Operate unit in the cooling cycle. Room temperature
should be approximately 7.2 to 43.3 C dry bulb. Loop
3. Verify that the compressor is on and that the water flow
rate is correct by measuring pressure drop through the
heat exchanger using pressure/temperature plugs. Check
the elevation and cleanliness of the condensate lines; any
dripping could be a sign of a blocked line. Be sure the
condensate trap includes a water seal.
22
4. Check the temperature of both supply and discharge
water.
to ensure proper start-up and continued efficient operation of
the system. Follow the steps below to properly flush the loop:
5. Air temperature drop across the coil should be checked
when compressor is operating. Air temperature drop
should be between –9.4 and –3.9 C.
1. Verify power is off.
2. Install the system with the supply hose connected directly
to the return riser valve. Use a single length of flexible
hose.
Unit Start-Up in Heating Mode
3. Open all air vents. Fill the system with water. DO NOT
allow system to overflow. Bleed all air from the system.
Pressurize and check the system for leaks and repair as
appropriate.
4. Verify that all strainers are in place. Carrier recommends
a strainer with a no. 20 stainless steel wire mesh. Start the
pumps, and systematically check each vent to ensure that
all air is bled from the system.
5. Verify that make-up water is available. Adjust makeup
water as required to replace the air which was bled from
the system. Check and adjust the water/air level in the ex-
pansion tank.
6. Set the boiler to raise the loop temperature to approxi-
mately 30 C. Open a drain at the lowest point in the sys-
tem. Adjust the make-up water replacement rate to equal
the rate of bleed.
NOTE: Operate the unit in heating cycle after checking the
cooling cycle. Allow 5 minutes between tests for the pressure
or reversing valve to equalize.
1. Turn thermostat to lowest setting and set thermostat
switch to HEAT position.
2. Slowly turn the thermostat to a higher temperature until
the compressor activates.
3. Check for warm air delivery at the unit grille within a few
minutes after the unit has begun to operate.
4. Check the temperature of both supply and discharge
water.
5. Air temperature rise across the coil should be checked
when compressor is operating. Air temperature rise
should be between –6.7 and –1.1 C after 15 minutes at
load.
6. Check for vibration, noise and water leaks.
7. Refill the system and add trisodium phosphate in a pro-
portion of approximately 0.5 kg per 750 L of water (or
other equivalent approved cleaning agent). Reset the boil-
er to raise the loop temperature to 38 C. Circulate the so-
lution for a minimum of 8 to 24 hours. At the end of this
period, shut off the circulating pump and drain the solu-
tion. Repeat system cleaning if desired.
8. When the cleaning process is complete, remove the short-
circuited hoses. Reconnect the hoses to the proper supply,
and return the connections to each of the units. Refill the
system and bleed off all air.
9. Test the system pH with litmus paper. The system water
should be in the range of pH 6.0 to 8.5 (see Table 2). Add
chemicals, as appropriate to maintain neutral pH levels.
10. When the system is successfully cleaned, flushed, refilled
and bled, check the main system panels, safety cutouts
and alarms. Set the controls to properly maintain loop
temperatures.
Flow Regulation — Flow regulation can be accom-
plished by two methods. Most water control valves have a flow
adjustment built into the valve. By measuring the pressure drop
through the unit heat exchanger, the flow rate can be deter-
mined using Table 11. Adjust the water control valve until the
flow of 0.09 to 0.13 L/s is achieved. Since the pressure con-
stantly varies, two pressure gages may be needed in some
applications.
An alternative method is to install a flow control device.
These devices are typically an orifice of plastic material de-
signed to allow a specified flow rate that are mounted on the
outlet of the water control valve. Occasionally these valves
produce a velocity noise that can be reduced by applying
some back pressure. To accomplish this, slightly close the
leaving isolation valve of the well water setup.
WARNING
DO NOT use “Stop Leak” or similar chemical agent in
this system. Addition of chemicals of this type to the loop
water will foul the heat exchanger and inhibit unit opera-
tion.
Electrical shock can cause personal injury and death. Shut
off all power to this equipment during installation. There
may be more than one disconnect switch. Tag all discon-
nect locations to alert others not to restore power until
flushing is completed.
11. Restore power.
Antifreeze may be added before, during or after the
flushing process. However, depending on when it is added
in the process, it can be wasted. Refer to the Antifreeze sec-
tion for more detail.
Loop static pressure will fluctuate with the seasons. Pres-
sures will be higher in the winter months than during the
warmer months. This fluctuation is normal and should be
considered when charging the system initially. Run the unit
in either heating or cooling for several minutes to condition
the loop to a homogenous temperature.
When complete, perform a final flush and pressurize the
loop to a static pressure of 275 to 345 kPa for winter months
or 100 to 140 kPa for summer months.
After pressurization, be sure to remove the plug from the
end of the loop pump motor(s) to allow trapped air to be
discharged and to ensure the motor housing has been flood-
ed. Be sure the loop flow center provides adequate flow
through the unit by checking pressure drop across the heat
exchanger.
Table 11 — Coaxial Water Pressure Drop
50HQP
UNIT
SIZE
PRESSURE DROP (kPa)
L/s
–1 C
10 C
21 C
32 C
0.6
0.9
1.3
0.8
1.1
1.5
0.9
1.4
1.9
8.3
22.8
42.7
45.4
68.1
90.9
56.8
85.2
113.6
6.2
19.1
36.5
14.5
36.5
64.1
27.6
59.3
100.0
3.4
14.5
29.0
11.7
31.0
54.5
22.1
49.6
83.4
2.1
12.4
26.2
9.0
24.8
45.5
15.2
37.9
67.6
072
096
120
Flushing — Once the piping is complete, final purging and
loop charging is needed. A flush cart pump of at least 1.5 hp is
needed to achieve adequate flow velocity in the loop to purge
air and dirt particles from the loop. Flush the loop in both direc-
tions with a high volume of water at a high velocity. Cleaning
and flushing the piping system is the single most important step
NOTE: Carrier strongly recommends all piping connections,
both internal and external to the unit, be pressure tested by an
appropriate method prior to any finishing of the interior space
23
or before access to all connections is limited. Test pressure
may not exceed the maximum allowable pressure for the unit
and all components within the water system. Carrier will not
be responsible or liable for damages from water leaks due to
inadequate or lack of a pressurized leak test, or damages
caused by exceeding the maximum pressure rating during
installation.
Ground Coupled, Closed Loop and Plateframe
Heat Exchanger Well Systems — These systems
allow water temperatures from –1.1 to 43.3 C. The external
loop field is divided up into 51 mm polyethylene supply and
return lines. Each line has valves connected in such a way
that upon system start-up, each line can be isolated for flush-
ing using only the system pumps. Air separation should be
located in the piping system prior to the fluid re-entering the
loop field.
Antifreeze — In areas where entering loop temperatures
drop below 4.4 C or where piping will be routed through areas
subject to freezing, antifreeze is needed.
Alcohols and glycols are commonly used as antifreeze
agents. Freeze protection should be maintained to 8.3° C below
the lowest expected entering loop temperature. For example, if
the lowest expected entering loop temperature is –1.1 C, the
leaving loop temperature would be –5.6 to –3.9 C. Therefore,
the freeze protection should be at –9.4 C (–1.1 C – 8.3 C =
–9.4 C).
OPERATION
Power Up Mode — The unit will not operate until all
the inputs, terminals and safety controls are checked for
normal operation.
NOTE: The compressor will have a 5-minute anti-short
cycle upon power up.
Units with Aquazone™ Complete C Control
IMPORTANT: All alcohols should be pre-mixed and
pumped from a reservoir outside of the building or intro-
duced under water level to prevent alcohols from fuming.
STANDBY — Y and W terminals are not active in Standby
mode, however the O and G terminals may be active, de-
pending on the application. The compressor will be off.
COOLING — Y and O terminals are active in Cooling
mode. After power up, the first call to the compressor will
initiate a 5 to 80 second random start delay and a 5-minute
anti-short cycle protection time delay. After both delays are
complete, the compressor is energized.
NOTE: On all subsequent compressor calls the random start
delay is omitted.
HEATING STAGE 1 — Terminal Y is active in heating
stage 1. After power up, the first call to the compressor will
initiate a 5 to 80 second random start delay and a 5-minute
anti-short cycle protection time delay. After both delays are
complete, the compressor is energized.
Calculate the total volume of fluid in the piping system. See
Table 12. Use the percentage by volume in Table 13 to deter-
mine the amount of antifreeze to use. Antifreeze concentration
should be checked from a well mixed sample using a hydrome-
ter to measure specific gravity.
FREEZE PROTECTION SELECTION — The –1.1 C FP1
factory setting (water) should be used to avoid freeze damage
to the unit.
Once antifreeze is selected, the JW3 jumper (FP1) should
be clipped on the control to select the low temperature
(antifreeze –12.2 C) set point to avoid nuisance faults.
NOTE: On all subsequent compressor calls the random start
delay is omitted.
HEATING STAGE 2 — To enter Stage 2 mode, terminal W
is active (Y is already active). Also, the G terminal must be
active or the W terminal is disregarded. The compressor re-
lay will remain on and EH1 is immediately turned on. EH2
will turn on after 10 minutes of continual stage 2 demand.
Cooling Tower/Boiler Systems — These systems
typically use a common loop maintained at 15.6 C to 32.2 C.
The use of a closed circuit evaporative cooling tower with a
secondary heat exchanger between the tower and the water
loop is recommended. If an open type cooling tower is
used continuously, chemical treatment and filtering will be
necessary.
NOTE: EH2 will not turn on (or if on, will turn off) if FP1
temperature is greater than 7.2 C and FP2 is greater than
43.3 C.
EMERGENCY HEAT — In emergency heat mode, termi-
nal W is active while terminal Y is not. Terminal G must be
active or the W terminal is disregarded. EH1 is immediately
turned on. EH2 will turn on after 5 minutes of continual
emergency heat demand.
Table 12 — Approximate Fluid Volume (L)
per 30 M of Pipe
PIPE
DIAMETER (in.) [mm] VOLUME (gal.) [L]
Copper
1 [25.4]
1.25 [31.8]
1.5 [38.1]
4.1 [15.5]
6.4 [24.2]
9.2 [34.8]
Rubber Hose
Polyethylene
1 [25.4]
3.9 [14.8]
3/4 IPS SDR11
1 IPS SDR11
11/4 IPS SDR11
1/2 IPS SDR11
2 IPS SDR11
11/4 IPS SCH40
11/2 IPS SCH40
2 IPS SCH40
2.8 [10.6]
4.5 [17.0]
8.0 [30.8]
10.9 [41.3]
18.0 [68.1]
8.3 [31.4]
10.9 [41.3]
17.0 [64.4]
Units with Aquazone Deluxe D Control
STANDBY/FAN ONLY — The compressor will be off.
The Fan Enable, Fan Speed, and reversing valve (RV) relays
will be on if inputs are present. If there is a Fan 1 demand,
the Fan Enable will immediately turn on. If there is a Fan 2
demand, the Fan Enable and Fan Speed will immediately
turn on.
LEGEND
IPS — Internal Pipe Size
SCH — Schedule
SDR — Standard Dimensional Ratio
NOTE: DIP switch 5 on S1 does not have an effect upon
Fan 1 and Fan 2 outputs.
HEATING STAGE 1 — In Heating Stage 1 mode, the Fan
Enable and Compressor relays are turned on immediately.
Once the demand is removed, the relays are turned off and
the control reverts to Standby mode. If there is a master/
slave or dual compressor application, all compressor relays
and related functions will operate per their associated DIP
switch 2 setting on S1.
NOTE: Volume of heat exchanger is approximately 3.78 liters.
Table 13 — Antifreeze Percentages by Volume
MINIMUM TEMPERATURE FOR FREEZE
PROTECTION (C)
ANTIFREEZE
Methanol (%)
–12.2
–9.4
–6.7
–3.9
25
21
16
10
100% USP Food Grade
Propylene Glycol (%)
Ethanol (%)
HEATING STAGE 2 — In Heating Stage 2 mode, the Fan
Enable and Compressor relays are remain on. The Fan
Speed relay is turned on immediately and turned off
38
29
30
25
22
20
15
14
24
immediately once the demand is removed. The control re-
verts to Heating Stage 1 mode. If there is a master/slave or
dual compressor application, all compressor relays and re-
lated functions will operate per their associated DIP switch
2 setting on S1.
HEATING STAGE 3 — In Heating Stage 3 mode, the Fan
Enable, Fan Speed and Compressor relays remain on. The
EH1 output is turned on immediately. With continuing Heat
Stage 3 demand, EH2 will turn on after 10 minutes. EH1
and EH2 are turned off immediately when the Heating Stage
3 demand is removed. The control reverts to Heating Stage
2 mode.
Output EH2 will be off if FP1 is greater than 7.2 C AND
FP2 (when shorted) is greater than 43.3 C during Heating
Stage 3 mode. This condition will have a 30-second
recognition time. Also, during Heating Stage 3 mode, EH1,
EH2, Fan Enable, and Fan Speed will be ON if G input is
not active.
EMERGENCY HEAT — In Emergency Heat mode, the
Fan Enable and Fan Speed relays are turned on. The EH1
output is turned on immediately. With continuing Emergen-
cy Heat demand, EH2 will turn on after 5 minutes. Fan En-
able and Fan Speed relays are turned off after a 60-second
delay. The control reverts to Standby mode.
also power on and off during Test mode. See Tables 14-16. To
exit Test mode, short the terminals for 3 seconds or cycle the
power 3 times within 60 seconds.
NOTE: The Deluxe D control has a flashing code and alarm
relay cycling code that will both have the same numerical
label. For example, flashing code 1 will have an alarm relay
cycling code 1. Code 1 indicates the control has not faulted
since the last power off to power on sequence.
Retry Mode — In Retry mode, the status LED will start to
flash slowly to signal that the control is trying to recover from
an input fault. The control will stage off the outputs and try to
again satisfy the thermostat used to terminal Y. Once the ther-
mostat input calls are satisfied, the control will continue normal
operation.
NOTE: If 3 consecutive faults occur without satisfying the
thermostat input call to terminal Y, the control will go into
lockout mode. The last fault causing the lockout is stored in
memory and can be viewed by entering Test mode.
Aquazone™ Deluxe D Control LED Indica-
tors — There are 3 LED indicators on the Deluxe D control:
STATUS LED — Status LED indicates the current status or
mode of the Deluxe D control. The Status LED light is green.
TEST LED — Test LED will be activated any time the De-
luxe D control is in Test mode. The Test LED light is yellow.
FAULT LED — Fault LED light is red. The fault LED will
always flash a code representing the last fault in memory. If
there is no fault in memory, the fault LED will flash code 1 on
the and appear as 1 fast flash alternating with a 10-second
pause. See Table 16.
Output EH1, EH2, Fan Enable, and Fan Speed will be
ON if the G input is not active during Emergency Heat
mode.
COOLING STAGE 1 — In Cooling Stage 1 mode, the Fan
Enable, compressor and RV relays are turned on immediate-
ly. If configured as stage 2 (DIP switch set to OFF) then the
compressor and fan will not turn on until there is a stage 2
demand. The Fan Enable and compressor relays are turned
off immediately when the Cooling Stage 1 demand is re-
moved. The control reverts to Standby mode. The RV relay
remains on until there is a heating demand. If there is a mas-
ter/slave or dual compressor application, all compressor re-
lays and related functions will track with their associated
DIP switch 2 on S1.
Table 14 — Complete C Control Current LED
Status and Alarm Relay Operations
LED STATUS
DESCRIPTION OF OPERATION
ALARM RELAY
Normal Mode
Open
Cycle
(closed 5 sec.,
Open 25 sec.)
On
Normal Mode with
PM Warning
Complete C Control is
non-functional
COOLING STAGE 2 — In Cooling Stage 2 mode, the Fan
Enable, compressor and RV relays remain on. The Fan
Speed relay is turned on immediately and turned off once
the Cooling Stage 2 demand is removed. The control reverts
to Cooling Stage 1 mode. If there is a master/slave or dual
compressor application, all compressor relays and related
functions will track with their associated DIP switch 2 on
S1.
NIGHT LOW LIMIT (NLL) STAGED HEATING — In
NLL staged Heating mode, the override (OVR) input be-
comes active and is recognized as a call for heating and the
control will immediately go into a Heating Stage 1 mode.
With an additional 30 minutes of NLL demand, the control
will go into Heating Stage 2 mode. With another additional
30 minutes of NLL demand, the control will go into Heating
Stage 3 mode.
Off
Open
Fault Retry
Over/Under Voltage Shutdown
Lockout
Open
Open
(Closed after
15 minutes)
Slow Flash
Fast Flash
Closed
Flashing Code 1 Test Mode — No fault in memory
Flashing Code 2 Test Mode — HP Fault in memory
Flashing Code 3 Test Mode — LP Fault in memory
Flashing Code 4 Test Mode — FP1 Fault in memory
Flashing Code 5 Test Mode — FP2 Fault in memory
Flashing Code 6 Test Mode — CO Fault in memory
Cycling Code 1
Cycling Code 2
Cycling Code 3
Cycling Code 4
Cycling Code 5
Cycling Code 6
Test Mode — Over/Under
shutdown in memory
Flashing Code 7
Cycling Code 7
Cycling Code 8
Cycling Code 9
Flashing Code 8
Flashing Code 9
Test Mode — PM in memory
Test Mode — FP1/FP2
Swapped fault in memory
LEGEND
SYSTEM TEST
CO
FP
HP
—
—
—
Condensate Overflow
System testing provides the ability to check the control
operation. The control enters a 20-minute Test mode by mo-
mentarily shorting the test pins. All time delays are in-
creased 15 times.
Freeze Protection
High Pressure
LED — Light-Emitting Diode
LP
PM
—
—
Low Pressure
Performance Monitor
NOTES:
Test Mode — To enter Test mode on Complete C or De-
luxe D controls, cycle the fan 3 times within 60 seconds. The
LED (light-emitting diode) will flash a code representing the
last fault when entering the Test mode. The alarm relay will
1. Slow flash is 1 flash every 2 seconds.
2. Fast flash is 2 flashes every 1 second.
3. EXAMPLE: “Flashing Code 2” is represented by 2 fast flashes followed
by a 10-second pause. This sequence will repeat continually until the
fault is cleared.
25
Table 15 — Complete C Control LED Code and
Fault Descriptions
LED
FAULT
No fault in memory
DESCRIPTION
CODE
1
2
3
4
5
6
There has been no fault since the last power-down to power-up sequence
HP open instantly
High-Pressure Switch
Low-Pressure Switch
LP open for 30 continuous seconds before or during a call (bypassed for first 60 seconds)
FP1 below Temp limit for 30 continuous seconds (bypassed for first 60 seconds of operation)
FP2 below Temp limit for 30 continuous seconds (bypassed for first 60 seconds of operation)
Sense overflow (grounded) for 30 continuous seconds
Freeze Protection Coax — FP1
Freeze Protection Air Coil — FP2
Condensate overflow
7
Over/Under Voltage Shutdown
"R" power supply is <19VAC or >30VAC
(Autoreset)
8
9
PM Warning
Performance Monitor Warning has occurred.
FP1 and FP2 Thermistors are swapped FP1 temperature is higher than FP2 in heating/test mode, or FP2 temperature is higher than FP1 in cooling/
test mode.
LEGEND
FP
HP
—
—
Freeze Protection
High Pressure
LED — Light-Emitting Diode
LP
PM
—
—
Low Pressure
Performance Monitor
Table 16 — Aquazone™ Deluxe D Control Current LED Status and Alarm Relay Operations
STATUS LED
(Green)
TEST LED
(Yellow)
DESCRIPTION
Normal Mode
FAULT LED (Red)
Flash Last Fault Code in Memory
Flashing Code 8
ALARM RELAY
On
Off
Open
Cycle (closed 5 sec,
open 25 sec, …)
Normal Mode with PM
On
Off
Deluxe D Control is
non-functional
Off
Off
Off
Open
Test Mode
Night Setback
ESD
Invalid T-stat Inputs
No Fault in Memory
HP Fault
—
On
—
—
Flash Last Fault Code in Memory
Flash Last Fault Code in Memory
Flash Last Fault Code in Memory
Flash Last Fault Code in Memory
Flashing Code 1
Cycling Appropriate Code
Flashing Code 2
Flashing Code 3
Flashing Code 4
On
—
—
—
Open
Open
Open
Open
Open
—
Off
Off
Off
Off
Off
Off
Off
Off
Off
Off
Off
Off
Slow Flash
Slow Flash
Slow Flash
Slow Flash
Slow Flash
Slow Flash
Fast Flash
Fast Flash
Fast Flash
Fast Flash
Fast Flash
Flashing Code 2
Flashing Code 3
Flashing Code 4
Flashing Code 5
Flashing Code 6
Flashing Code 7
Flashing Code 2
Flashing Code 3
LP Fault
FP1 Fault
FP2 Fault
CO Fault
Open
Over/Under Voltage
HP Lockout
LP Lockout
FP1 Lockout
FP2 Lockout
CO Lockout
Open (closed after 15 minutes)
Closed
Closed
Closed
Closed
Closed
Flashing Code 4
Flashing Code 5
Flashing Code 6
LEGEND
NOTES:
1. If there is no fault in memory, the Fault LED will flash code 1.
2. Codes will be displayed with a 10-second Fault LED pause.
3. Slow flash is 1 flash every 2 seconds.
CO — Condensate Overflow
ESD — Emergency Shutdown
FP
— Freeze Protection
4. Fast flash is 2 flashes every 1 second.
HP — High Pressure
LP — Low Pressure
PM — Performance Monitor
5. EXAMPLE: “Flashing Code 2” is represented by 2 fast flashes fol-
lowed by a 10-second pause. This sequence will repeat continually
until the fault is cleared.
SERVICE
IMPORTANT: To avoid the release of refrigerant into the
atmosphere, the refrigerant circuit of this unit must only be
serviced by technicians which meet local, state and federal
proficiency requirements.
Perform the procedures outlined below periodically, as
indicated.
IMPORTANT: When a compressor is removed from this
unit, system refrigerant circuit oil will remain in the com-
pressor. To avoid leakage of compressor oil, the refrigerant
lines of the compressor must be sealed after it is removed.
IMPORTANT: To prevent injury or death due to electrical
shock or contact with moving parts, open unit disconnect
switch before servicing unit.
IMPORTANT: All refrigerant discharged from this unit
must be recovered without exception. Technicians must fol-
low industry accepted guidelines and all local, state and fed-
eral statutes for the recovery and disposal of refrigerants.
26
comb of the correct tooth spacing when straightening mashed
or bent coil fins.
Filters — Filters must be clean for maximum performance.
Inspect filters every month under normal operating conditions.
replace when necessary.
Condenser Cleaning — Water-cooled condensers may
require cleaning of scale (water deposits) due to improperly
maintained closed-loop water systems. Sludge build-up may
need to be cleaned in an open water tower system due to
induced contaminants.
IMPORTANT: Units should never be operated with-
out a filter.
Washable, high efficiency, electrostatic filters, when dirty,
can exhibit a very high pressure drop for the fan motor and re-
duce air flow, resulting in poor performance. It is especially im-
portant to provide consistent washing of these filters (in the op-
posite direction of the normal air flow) once per month using a
high pressure wash.
Local water conditions may cause excessive fouling or
pitting of tubes. Condenser tubes should therefore be cleaned at
least once a year, or more often if the water is contaminated.
Proper water treatment can minimize tube fouling and
pitting. If such conditions are anticipated, water treatment
analysis is recommended. Refer to the Carrier System Design
Manual, Part 5, for general water conditioning information.
Water Coil — Keep all air out of the water coil. Check
open loop systems to be sure the well head is not allowing air
to infiltrate the water line. Always keep lines airtight.
CAUTION
DIRECT GROUND WATER APPLICATIONS — If the
system is installed in an area with a known high mineral con-
tent (125 ppm or greater) in the water, it is best to establish a
periodic maintenance schedule with the owner so the coil can
be checked regularly.
Should periodic coil cleaning be necessary, use standard
coil cleaning procedures, which are compatible with the heat
exchanger material and copper water lines. Generally, the more
water flowing through the unit, the less chance for scaling.
Therefore, 1.6 L/m per kW is recommended as a minimum
flow. Minimum flow rate for entering water temperatures be-
low 10.0 C is 2.2 L/m per kW.
Follow all safety codes. Wear safety glasses and rubber
gloves when using inhibited hydrochloric acid solution.
Observe and follow acid manufacturer’s instructions. Fail-
ure to follow these safety precautions could result in per-
sonal injury or equipment or property damage.
Clean condensers with an inhibited hydrochloric acid solu-
tion. The acid can stain hands and clothing, damage concrete,
and, without inhibitor, damage steel. Cover surroundings to
guard against splashing. Vapors from vent pipe are not harmful,
but take care to prevent liquid from being carried over by the
gases.
ALL OTHER WATER LOOP APPLICATIONS — Gener-
ally, water coil maintenance is not needed for closed loop sys-
tems. However, if the piping is known to have high dirt or de-
bris content, it is best to establish a periodic maintenance
schedule with the owner so the water coil can be checked regu-
larly. Dirty installations are typically the result of deterioration
of iron or galvanized piping or components in the system.
Open cooling towers requiring heavy chemical treatment and
mineral buildup through water use can also contribute to higher
maintenance. Should periodic coil cleaning be necessary, use
standard coil cleaning procedures, which are compatible with
both the heat exchanger material and copper water lines. Gen-
erally, the more water flowing through the unit, the less chance
for scaling. However, flow rates over 3.9 L/m per kW can pro-
duce water (or debris) velocities that can erode the heat ex-
changer wall and ultimately produce leaks.
Warm solution acts faster, but cold solution is just as effec-
tive if applied for a longer period.
GRAVITY FLOW METHOD — Do not add solution faster
than vent can exhaust the generated gases.
When condenser is full, allow solution to remain overnight,
then drain condenser and flush with clean water. Follow acid
manufacturer’s instructions. See Fig. 22.
FORCED CIRCULATION METHOD — Fully open vent
pipe when filling condenser. The vent may be closed when
condenser is full and pump is operating. See Fig. 23.
Regulate flow to condenser with a supply line valve. If
pump is a nonoverloading type, the valve may be fully closed
while pump is running.
FILL CONDENSER WITH
IMPORTANT: To avoid fouled machinery and extensive
unit clean-up, DO NOT operate units without filters in
place. DO NOT use equipment as a temporary heat source
during construction.
CLEANING SOLUTION. DO
PAIL
NOT ADD SOLUTION
MORE RAPIDLY THAN
VENT CAN EXHAUST
GASES CAUSED BY
FUNNEL
CHEMICAL ACTION.
Condensate Drain Pans — Check condensate drain
pans for algae growth twice a year. If algae growth is apparent,
consult a water treatment specialist for proper chemical treat-
ment. The application of an algaecide every three months will
typically eliminate algae problems in most locations.
1-IN.
(25 mm)
PIPE
VENT
PIPE
1.5 m APPROX
Refrigerant System — Verify air and water flow rates
are at proper levels before servicing. To maintain sealed circuit-
ry integrity, do not install service gages unless unit operation
appears abnormal.
1.0 TO 1.2 m
CONDENSER
Condensate Drain Cleaning — Clean the drain line
and unit drain pan at the start of each cooling season. Check
flow by pouring water into drain. Be sure trap is filled to main-
tain an air seal.
PAIL
Air Coil Cleaning — Remove dirt and debris from evap-
orator coil as required by condition of the coil. Clean coil with
a stiff brush, vacuum cleaner, or compressed air. Use a fin
a50-8586
Fig. 22 — Gravity Flow Method
27
Refrigerant Charging
WARNING
GAS VENT
PUMP
PRIMING
CONN.
GLOBE
VALVES
To prevent personal injury, wear safety glasses and gloves
when handling refrigerant. Do not overcharge system —
this can cause compressor flooding.
SUCTION
SUPPLY
PUMP
SUPPORT
1-IN.
(25 mm)
PIPE
NOTE: Do not vent or depressurize unit refrigerant to atmo-
sphere. Remove and recover refrigerant following accepted
practices.
CONDENSER
TANK
Air Coil Fan Motor Removal
CAUTION
REMOVE WATER
REGULATING VALVE
RETURN
FINE MESH
SCREEN
Before attempting to remove fan motors or motor mounts,
place a piece of plywood over evaporator coils to prevent
coil damage.
Fig. 23 — Forced Circulation Method
Motor power wires need to be disconnected from motor
terminals before motor is removed from unit.
1. Shut off unit main power supply.
2. Loosen bolts on mounting bracket so that fan belt can be
removed.
For average scale deposit, allow solution to remain in con-
denser overnight. For heavy scale deposit, allow 24 hours.
Drain condenser and flush with clean water. Follow acid manu-
facturer’s instructions.
Compressor — Conduct annual amperage checks to in-
sure that amp draw is no more than 10% greater than indicated
on the serial plate data.
3. Loosen and remove the 2 motor mounting bracket bolts
on left side of bracket.
4. Slide motor/bracket assembly to extreme right and lift out
through space between fan scroll and side frame. Rest
motor on a high platform such as a step ladder. Do not
allow motor to hang by its power wires.
Fan Motors — All units have lubricated fan motors. Fan
motors should never be lubricated unless obvious, dry opera-
tion is suspected. Periodic maintenance oiling is not recom-
mended, as it will result in dirt accumulating in the excess oil
and cause eventual motor failure. Conduct annual dry opera-
tion check and amperage check to ensure amp draw is no more
than 10% greater than indicated on serial plate data.
Blower Fan Sheaves — Factory-supplied drives are
pre-aligned and tensioned, however, it is recommended that the
belt tension and alignment be checked before starting the unit.
Always check the drive alignment after adjusting belt tension.
Sheave and belt information is shown in Table 17.
Each factory-assembled fan, shaft, and drive sheave assem-
bly is precision aligned and balanced. If excessive unit
vibration occurs after field replacement of sheaves, the unit
should be rebalanced. To change the drive ratio, follow the
steps in the Blower Fan Performance Adjustment section.
After 1 to 3 minutes of operation, check the belt tension.
Also check tension frequently during the first 24 hours of oper-
ation and adjust if necessary. Periodically check belt tension
throughout the run-in period, which is normally the initial
72 hours of operation.
ALIGNMENT — Make sure that fan shafts and motor shafts
are parallel and level. The most common causes of misalign-
ment are nonparallel shafts and improperly located sheaves.
Where shafts are not parallel, belts on one side are drawn tight-
er and pull more than their share of the load. As a result, these
belts wear out faster, requiring the entire set to be replaced be-
fore it has given maximum service. If misalignment is in the
sheave, belts enter and leave the grooves at an angle, causing
excessive belt and sheave wear.
Belt — Check that the belt is tight. Retighten if needed. Re-
place if it is split or cracked.
Air Coil — The air coil must be cleaned to obtain maximum
performance. Check once a year under normal operating condi-
tions and, if dirty, brush or vacuum clean. Care must be taken
not to damage the aluminum fins while cleaning.
Checking System Charge — Units are shipped with
full operating charge. If recharging is necessary:
1. Insert thermometer bulb in insulating rubber sleeve on
liquid line near filter drier. Use a digital thermometer for
all temperature measurements. DO NOT use a mercury
or dial-type thermometer.
2. Connect pressure gage to discharge line near compressor.
3. After unit conditions have stabilized, read head pressure
on discharge line gage.
NOTE: Operate unit a minimum of 15 minutes before
checking charge.
4. From standard field-supplied Pressure-Temperature chart
for R-410A, find equivalent saturated condensing
temperature.
5. Read liquid line temperature on thermometer; then
subtract from saturated condensing temperature. The dif-
ference equals subcooling temperature.
Shaft Alignment — Check shaft alignment by measuring the
distance between the shafts at 3 or more locations. If the dis-
tances are equal, then the shafts are parallel.
Sheave Alignment
1. To check the location of the fixed sheaves on the shafts,
use a straightedge or a piece of string. If the sheaves are
properly aligned, the string will touch them at the points
indicated by the arrows in Fig. 24. Rotate each sheave a
half revolution to determine whether the sheave is wob-
bly or the drive shaft is bent. Correct any misalignment.
2. With sheaves aligned, tighten cap screws evenly and
progressively.
28
NOTE: There should be a 3 to 6 mm gap between the
mating part hub and the bushing flange. If the gap is
closed, the bushing is probably the wrong size.
4. Loosen the 5/16-in. hex nuts on the grommet motor adjust-
ment bolts (2 per bolt). To increase the belt tension loosen
the top hex nut. To decrease the belt tension loosen the
bottom hex nut.
5. Turn the bolts by hand to the desired position then tighten
the 5/16-in. hex nuts ( 2 per bolt).
3. With taper-lock bushed hubs, be sure the bushing bolts
are tightened evenly to prevent side-to-side pulley wob-
ble. Check by rotating sheaves and rechecking sheave
alignment. When substituting field-supplied sheaves for
factory-supplied sheaves, only the motor sheave should
be changed.
6. Lower the motor assembly.
7. Install the belt.
8. Tension the belt per section below.
9. Restore power to the unit.
BELT TENSION ADJUSTMENT — Using a gage, apply
4 lb of force to the center of the belt and adjust the tension until
a deflection of 1/64-in. is achieved for every inch of shaft center
distance. See Fig. 25.
Blower Fan Performance Adjustment —
The
unit is supplied with variable sheave drive on the fan motor to
adjust for differing airflows at various ESP conditions. Select
an airflow requirement on the left side of the table, then move
horizontally to right under the required ESP for the sheave
turns open, rpm and horsepower for that condition. Fully
closed, the sheave will produce the highest static capability
(higher rpm).
Ideal belt tension is the lowest value under which belt slip
will not occur at peak load conditions.
To change fan speeds from factory settings:
1. Shut off unit power supply.
2. Remove belt from motor sheave.
3. Lift motor assembly.
LB FORCE
a50-7135tf
DEFLECTION
a50-7136ef
Fig. 25 — Fan Belt Tension
Fig. 24 — Sheave Alignment
Table 17 — Blower Sheave and Belt Specifications
DRIVE PACKAGE
B†
BK85 X 1
1VP34 X 7/8
1
UNIT SIZE
COMPONENT
50HQP
A*
BK67 X 1
1VP34 X 7/8
1
C**
BK67 X 1
1VP44 X 7/8
1
BLOWER SHEAVE
MOTOR SHEAVE
072
MOTOR HP
BELT
B X 46
B X 50
B X 48
BLOWER SHEAVE
MOTOR SHEAVE
BK67 X 1
1VP40 X 7/8
2
BK77 X 1
1VP34 X 7/8
2
BK62 X 1
1VP44 X 7/8
2
096
MOTOR HP
BELT
B X 46
B X 48
B X 46
BLOWER SHEAVE
MOTOR SHEAVE
BK67 X 1
1VP44 X 7/8
3
BK67 X 1
1VP34 X 7/8
3
BK67 X 1
1VP50 X 7/8
3
120
MOTOR HP
BELT
B X 48
B X 46
B X 48
*Airflow configurations J, K, N, and P.
†Airflow configurations Q, T, U, and V.
**Airflow configurations W, X, Z, and 1.
29
TROUBLESHOOTING
90.0
80.0
70.0
60.0
50.0
40.0
30.0
20.0
10.0
0.0
When troubleshooting problems with a WSHP, see
Table 18.
Thermistor — A thermistor may be required for single-
phase units where starting the unit is a problem due to low
voltage. See Fig. 26 for thermistor nominal resistance.
Control Sensors — The control system employs 2 nom-
inal 10,000 ohm thermistors (FP1 and FP2) that are used for
freeze protection. Be sure FP1 is located in the discharge fluid
and FP2 is located in the air discharge. See Fig. 27.
-17.7
-6.6
4.4
15.6
26.7
37.8
48.9
60.0
Temperature (C)
Fig. 26 — Thermistor Nominal Resistance
AIR
COIL
SUCTION
AIRFLOW
(°C)
AIRFLOW
(°C)
COMPRESSOR
THERMISTOR
EXPANSION
VALVE
COAX
DISCHARGE
FP2
FP1
CONDENSATE
OVERFLOW
(CO)
LIQUID
LINE
WATER IN
WATER OUT
AIR COIL
WATER
COIL
PROTECTION
FREEZE
PROTECTION
LEGEND
COAX — Coaxial Heat Exchanger
Airflow
a50-8163
Refrigerant Liquid Line Flow
Fig. 27 — FP1 and FP2 Thermistor Location
30
Table 18 — Troubleshooting
FAULT
HEATING COOLING
POSSIBLE CAUSE
SOLUTION
Main Power Problems
X
X
Green Status LED Off
Check line voltage circuit breaker and disconnect.
Check for line voltage between L1 and L2 on the contactor.
Check for 24-vac between R and C on controller.
Check primary/secondary voltage on transformer.
HP Fault — Code 2
High Pressure
X
X
Reduced or no water flow in Check pump operation or valve operation/setting.
cooling
Check water flow adjust to proper flow rate.
Water temperature out of
range in cooling
Bring water temperature within design parameters.
X
X
Reduced or no airflow in
heating
Check for dirty air filter and clean or replace.
Check fan motor operation and airflow restrictions.
Dirty air coil — construction dust, etc. Perform preventative mainte-
nance; Clean air coil.
High external static. Check duct design and downstream interference.
Air temperature out of range Bring return-air temperature within design parameters.
in heating
X
X
X
X
X
X
X
Overcharged with refrigerant Check superheat/subcooling vs. typical operating condition.
Bad HP switch
Insufficient charge
Check switch continuity and operation. Replace.
Check for refrigerant leaks.
LP Fault — Code 3
Low Pressure/Loss of
Charge
Compressor pump down at Check charge and start-up water flow.
start-up
FP1 Fault — Code 4
Water Freeze Protection
X
Reduced or no water flow in Check pump operation or water valve operation/setting.
heating
Plugged strainer or filter. Clean or replace.
Check water flow adjust to proper flow rate.
X
X
Inadequate antifreeze level Check antifreeze density with hydrometer.
Improper freeze protect set- Clip JW3 jumper for antifreeze (–12.2 C) use.
ting (–1.1 Cvs –12.2 C)
X
X
Water temperature out of
range
Bad thermistor
Reduced or no airflow in
cooling
Bring water temperature within design parameters.
X
X
Check temperature and impedance correlation.
Check for dirty air filter and clean or replace.
Check fan motor operation and airflow restrictions.
High external static. Check duct design and downstream interference.
FP2 Fault — Code 5
Air Coil Freeze
Protection
X
X
Air temperature out of range Too much cold vent air. Bring entering-air temperature within design
parameters.
Improper freeze protect set- Normal airside applications will require –1.1 C only.
ting (–1.1 Cvs –12.2 C)
X
X
X
X
X
X
X
Bad thermistor
Blocked drain
Improper trap
Poor drainage
Check temperature and impedance correlation.
Check for blockage and clean drain.
Check trap dimensions and location ahead of vent.
Check for piping slope away from unit.
Condensate Fault —
Code 6
Check slope of unit toward outlet.
Poor venting. Check vent location.
X
X
Moisture on sensor
Under voltage
Check for moisture shorting to air coil.
Check power supply and 24-vac voltage before and during operation.
Check power supply wire size.
Over/Under Voltage —
Code 7
(Auto Resetting)
X
Check compressor starting.
Check 24-vac and unit transformer tap for correct power supply voltage.
Check power supply voltage and 24 vac before and during operation.
Check 24-vac and unit transformer tap for correct power supply voltage.
X
X
X
X
Over voltage
Performance Monitor —
Code 8
Heating mode FP2> 51.7 C Check for poor airflow or overcharged unit.
Cooling mode FP1> 51.7 C Check for poor water flow or airflow.
OR FP2< 4.4 C
No Fault Code Shown
Unit Short Cycles
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
Compressor overload
Control board
Dirty air filter
Unit in Test mode
Unit selection
Compressor overload
Thermostat position
Unit locked out
Check and replace if necessary.
Reset power and check operation.
Check and clean air filter.
Reset power or wait 20 minutes for auto exit.
Unit may be oversized for space. Check sizing for actual load of space.
Check and replace if necessary.
Ensure thermostat set for heating or cooling operation.
Check for lockout codes. Reset power.
Check compressor overload. Replace if necessary.
Check Y and W wiring at heat pump. Jumper Y and R for compressor
operation in Test mode.
Only Fan Runs
Compressor overload
Thermostat wiring
LEGEND
FP — Freeze Protection
HP — High Pressure
LED — Light-Emitting Diode
LP — Low Pressure
RV — Reversing Valve
31
Table 18 — Troubleshooting (cont)
FAULT
HEATING COOLING
POSSIBLE CAUSE
SOLUTION
Only Compressor Runs
X
X
X
X
Thermostat wiring
Check G wiring at heat pump. Jumper G and R for fan operation.
Check Y and W wiring at heat pump. Jumper Y and R for compressor
operation in Test mode.
Jumper G and R for fan operation. Check for line voltage across BR
contacts.
Check fan power enable relay operation (if present).
Check for line voltage at motor. Check capacitor.
Set for cooling demand and check 24-vac on RV coil and at control.
If RV is stuck, run high pressure up by reducing water flow and while
operating engage and disengage RV coil voltage to push valve.
X
Fan motor relay
X
X
Fan motor
Reversing valve
Unit Does Not Operate in
Cooling
X
X
X
Thermostat setup
Thermostat wiring
Dirty filter
Reduced or no airflow in
heating
Check for ‘O’ RV setup not ‘B’.
Check O wiring at heat pump. Jumper O and R for RV coil.
Replace or clean.
Check for dirty air filter and clean or replace.
Check fan motor operation and airflow restrictions.
High external static. Check duct design and downstream interference.
Check for dirty air filter and clean or replace.
Check fan motor operation and airflow restrictions.
High external static. Check duct design and downstream interference.
Insufficient Capacity/
Not Cooling or Heating
Properly
X
X
X
X
Reduced or no airflow in
cooling
X
Leaky ductwork
Check supply and return-air temperatures at the unit and at distant
duct registers if significantly different, duct leaks are present.
X
X
X
X
X
X
Low refrigerant charge
Restricted metering device Check superheat and subcooling. Replace.
Defective reversing valve
Thermostat improperly
located
Check superheat and subcooling.
Perform RV touch test.
Check location and for air drafts behind thermostat.
X
X
X
X
X
X
Unit undersized
Recheck loads and sizing check sensible cooling load and heat pump
capacity.
Perform scaling check and clean if necessary.
Scaling in water heat
exchanger
Inlet water too hot or cold
Reduced or no airflow in
heating
X
X
Check load, loop sizing, loop backfill, ground moisture.
Check for dirty air filter and clean or replace.
Check fan motor operation and airflow restrictions.
High external static. Check duct design and downstream interference.
High Head Pressure
X
X
Reduced or no water flow in Check pump operation or valve operation/setting.
cooling
Check water flow adjust to proper flow rate.
Inlet water too hot
Check load, loop sizing, loop backfill, ground moisture.
X
Air temperature out of range Bring return-air temperature within design parameters.
in heating
X
Scaling in water heat
exchanger
Perform scaling check and clean if necessary.
X
X
X
X
Unit overcharged
Non-condensables in
system
Check superheat and subcooling. Reweigh in charge.
Vacuum system and reweigh in charge.
X
X
X
Restricted metering device Check superheat and subcooling. Replace.
Low Suction Pressure
Reduced water flow in
heating
Check pump operation or water valve operation/setting.
Plugged strainer or filter. Clean or replace.
Check water flow adjust to proper flow rate.
X
Water temperature out of
range
Bring water temperature within design parameters.
X
Reduced airflow in cooling Check for dirty air filter and clean or replace.
Check fan motor operation and airflow restrictions.
High external static. Check duct design and downstream interference.
X
X
Air temperature out of range Too much cold vent air. Bring entering air temperature within design
parameters.
X
X
X
Insufficient charge
Too high airflow
Poor performance
Too high airflow
Unit oversized
Check for refrigerant leaks.
Check blower.
See ‘Insufficient Capacity’ above.
Check blower.
Recheck loads and sizing check sensible cooling load and heat pump
capacity.
Low Discharge Air
Temperature in Heating
High Humidity
X
X
LEGEND
FP — Freeze Protection
HP — High Pressure
LED — Light-Emitting Diode
LP — Low Pressure
RV — Reversing Valve
32
Copyright 2010 Carrier Corporation
Manufacturer reserves the right to discontinue, or change at any time, specifications or designs without notice and without incurring obligations.
Catalog No. 04-53500077-01
Printed in U.S.A.
Form 50HQP-C1SI
Pg 34
11-10
Replaces: New
START-UP CHECKLIST
CUSTOMER:___________________________
MODEL NO.:___________________________
JOB NAME: _______________________________________
SERIAL NO.:____________________
DATE:_________
I. PRE-START-UP
DOES THE UNIT VOLTAGE CORRESPOND WITH THE SUPPLY VOLTAGE AVAILABLE? (Y/N)
HAVE THE POWER AND CONTROL WIRING CONNECTIONS BEEN MADE AND TERMINALS
TIGHT? (Y/N)
HAVE WATER CONNECTIONS BEEN MADE AND IS FLUID AVAILABLE AT HEAT EXCHANGER?
(Y/N)
HAS PUMP BEEN TURNED ON AND ARE ISOLATION VALVES OPEN? (Y/N)
HAS CONDENSATE CONNECTION BEEN MADE AND IS A TRAP INSTALLED? (Y/N)
IS AN AIR FILTER INSTALLED? (Y/N)
II. START-UP
IS FAN OPERATING WHEN COMPRESSOR OPERATES? (Y/N)
IF 3-PHASE SCROLL COMPRESSOR IS PRESENT, VERIFY PROPER ROTATION PER INSTRUCTIONS.
(Y/N)
UNIT VOLTAGE — COOLING OPERATION
PHASE AB VOLTS
PHASE BC VOLTS
(if 3 phase)
PHASE CA VOLTS
(if 3 phase)
PHASE AB AMPS
PHASE BC AMPS
(if 3 phase)
PHASE CA AMPS
(if 3 phase)
CONTROL VOLTAGE
IS CONTROL VOLTAGE ABOVE 21.6 VOLTS? (Y/N)
.
IF NOT, CHECK FOR PROPER TRANSFORMER CONNECTION.
TEMPERATURES
FILL IN THE ANALYSIS CHART ATTACHED.
COAXIAL HEAT COOLING CYCLE:
EXCHANGER
FLUID IN
C FLUID OUT
C FLUID OUT
C
kPa
kPa
L/s
L/s
HEATING CYCLE:
FLUID IN
C
C
C
AIR COIL
COOLING CYCLE:
AIR IN
C
C
AIR OUT
AIR OUT
HEATING CYCLE:
AIR IN
CL-1
HEATING CYCLE ANALYSIS
kPa
°C
DEW
POINT
AIR
COIL
SUCTION
°C
°C
COMPRESSOR
DISCHARGE
EXPANSION
VALVE
COAX
°C
LIQUID LINE
°C
kPa
°C
kPa
WATER IN
WATER OUT
LOOK UP PRESSURE DROP IN TABLE 11
TO DETERMINE FLOW RATE
COOLING CYCLE ANALYSIS
kPa
°C
DEW
POINT
AIR
COIL
SUCTION
°C
°C
COMPRESSOR
DISCHARGE
EXPANSION
VALVE
COAX
°C
LIQUID LINE
°C
°C
kPa
kPa
WATER IN
WATER OUT
LOOK UP PRESSURE DROP IN TABLE 11
TO DETERMINE FLOW RATE
HEAT OF EXTRACTION (ABSORPTION) OR HEAT OF REJECTION =
FLOW RATE (L/s) x TEMP. DIFF. (DEG. C) x
FLUID FACTOR* =
(kW)
SUPERHEAT = SUCTION TEMPERATURE – SUCTION SATURATION TEMPERATURE
(DEG C)
=
SUBCOOLING = DISCHARGE SATURATION TEMPERATURE – LIQUID LINE TEMPERATURE
(DEG C)
=
*Use 500 for water, 485 for antifreeze.
Copyright 2010 Carrier Corporation
Manufacturer reserves the right to discontinue, or change at any time, specifications or designs without notice and without incurring obligations.
Catalog No. 04-53500077-01 Printed in U.S.A. Form 50HQP-C1SI Pg CL-2 11-10 Replaces: New
|