HEAT PUMP INSTALLATION INSTRUCTIONS
Table of Contents
HEAT PUMP SAFETY.....................................................................1
SEQUENCE OF OPERATION ......................................................12
Cooling Cycle .............................................................................12
Heating Cycle .............................................................................12
Defrost Cycle..............................................................................12
Adjust Defrost System ...............................................................13
Troubleshoot the Defrost System..............................................14
TROUBLESHOOTING ..................................................................15
System Diagnostic Module ........................................................15
SYSTEM MAINTENANCE ............................................................17
ASSISTANCE OR SERVICE.........................................................17
INSTALLATION REQUIREMENTS................................................1
Tools and Parts ............................................................................2
System Requirements..................................................................2
Location Requirements................................................................2
Electrical Requirements ...............................................................4
Inspect Shipment.........................................................................4
Flush Refrigerant Lines ................................................................4
Connect Refrigerant Lines ...........................................................6
Make Electrical Connections .......................................................9
Complete Installation .................................................................11
Accessories ................................................................................17
WARRANTY ..................................................................................18
HEAT PUMP SAFETY
Your safety and the safety of others are very important.
We have provided many important safety messages in this manual and on your appliance. Always read and obey all safety
messages.
This is the safety alert symbol.
This symbol alerts you to potential hazards that can kill or hurt you and others.
All safety messages will follow the safety alert symbol and either the word “DANGER” or “WARNING.”
These words mean:
You can be killed or seriously injured if you don't immediately
follow instructions.
DANGER
You can be killed or seriously injured if you don't
instructions.
follow
WARNING
All safety messages will tell you what the potential hazard is, tell you how to reduce the chance of injury, and tell you what can
happen if the instructions are not followed.
INSTALLATION REQUIREMENTS
These instructions are intended as a general guide only for use by
qualified persons and do not supersede any national or local
codes in any way. The installation must comply with all state and
local codes as well as the National Electrical Code
I
The heat pump is designed and approved for outdoor use
only.
I
The heat pump must be installed with no ductwork in the
airstream. The outdoor fan is not designed to operate against
any additional static pressure.
Whirlpool Gold™ Model W4GH6
48488A006
Minimum Clearances
Transition from Horizontal to Vertical
This shows how to make a transition from horizontal to vertical.
A B
C
D
To
Power
Supply
Style 1
Style 2
48" Overhead
Clearance
(Discharge
Air)
To
A
G
Indoor
Unit
To
12" Clearance
(Inlet Air)
Indoor
Coil
B
C
B
C
E
F
F
D
D
E
E
30" Service
12" Clearance Between
Unit and Building
36" Clearance
A. Style 1—anchored
heavy nylon wire tie
B. Strap liquid line to
vapor line.
C. Liquid line
E. Metal sleeve
F. Wall stud
G. Style 2—automotive
muffler-type hanger
Access Clearance
(Inlet Air)
D. Vapor line—
wrapped in
armaflex
A. Weatherproof disconnect switch
B. NEC class 1 wiring
D. House thermostat
E. Seal openings
C. NEC class 2 wiring
Installing Vertical Runs (new construction shown)
This shows how to install line sets on vertical runs.
Line Set Isolation
NOTE: Similar installation practices should be used if line set is
to be installed on exterior of outside wall.
The following illustrations demonstrate procedures which ensure
proper refrigerant line set isolation.
IMPORTANT: Refrigerant lines must not contact structure.
B
Installing Horizontal Runs
This shows how to install line sets on horizontal runs.
A
C
C
D
H
NOTE: To hang line set from joist or rafter, use either metal
strapping material or anchored heavy nylon wire ties.
E
F
D
C
G
C
8'
G
H
E
B
D
A
I
8'
E
G
G
E
D
J
A
K
L
H
F
A. Metal strapping material
(around vapor line only)
B. Floor joist or roof rafter
C. Anchored heavy nylon wire tie G. Strap the vapor line to the floor
(around vapor line only)
D. Tape or wire tie
E. Metal sleeve
F. Tape or anchored heavy nylon
wire tie
A. Outside wall
D. Liquid line
E. Anchored heavy nylon
wire tie
F. Inside wall
G. Metal strapping material
H. Metal sleeve
I. Wood block
between studs
J. Caulk
K. Fiberglass
insulation
L. PVC pipe
B. Refrigerant lines
must not contact
wall.
C. Vapor line wrapped
in armaflex
joist or roof rafter at 8" intervals,
then strap the liquid line to the
vapor line.
3
Electrical Requirements
Inspect Shipment
WARNING
Excessive Weight Hazard
WARNING
Use two or more people to move and install
condensing unit or heat pump.
Failure to do so can result in back or other injury.
Electrical Shock Hazard
This heat pump is shipped in one package, completely
assembled and wired. The thermostat is shipped in a separate
carton when ordered.
Electrically ground condensing unit or heat pump.
Connect ground wire to ground lug.
1. Check the heat pump rating plate to confirm specifications
Use copper wire for supply connection.
Correct wire gauge is shown in the chart below.
are as ordered.
2. Upon receipt of equipment, carefully inspect it for possible
shipping damage. Take special care to examine the heat
pump inside the carton if the carton is damaged.
Failure to follow these instructions can result in
death or electrical shock.
If damage is found, it should be noted on the carrier’s freight bill.
Damage claims should be filed with the carrier immediately.
Claims of shortages should be filed with the seller within 5 days.
Rating Plate Ampacity
Less than 15
16 - 20
AWG
14
NOTE: If any damages are discovered and reported to the carrier,
do not install the heat pump because your claim may be denied.
12
Flush Refrigerant Lines
21 - 30
10
Refrigerant lines must be flushed by a licensed, EPA certified
refrigerant technician in accordance with established procedures.
31 - 50
8
NOTES:
I
R-410A outdoor systems are not recommended for use with
indoor systems that have used R-22 as the refrigerant.
However, if this unit is being matched with an approved line
set or indoor coil which was previously charged with R-22
refrigerant, or if it is being matched with a coil which was
manufactured before January of 1999, the R-22 coil and line
set must be flushed prior to installation.
NOTE: All outdoor wiring must be suitable for outdoor use. Use
copper conductors only.
I
All field wiring must be done in accordance with National
Electrical Code requirements, applicable requirements of UL,
or local codes, where applicable.
I
Electrical wiring, disconnect means and over-current
protection are to be supplied by the installer. Refer to the
rating plate for the maximum over-current protection,
minimum circuit ampacity, and operating voltage. See the
wiring diagrams in “Make Electrical Connections.”
I
Check the refrigerant lines for size and length. See “Connect
Refrigerant Lines.”
Flushing Connections
Inverted R-22 Cylinder
(Contains clean R-22 to
be used for flushing)
Low
High
Pressure
Pressure
Outdoor
System
Gauge Manifold
Closed
Vapor Line
Existing Vapor Line
Existing Liquid Line
Service Valve
Existing
Indoor Coil
Opened
Liquid Line
Service Valve
NOTE: The inverted R-22 cylinder must contain at least
the same amount of refrigerant as was recovered from
the existing system.
Tank Return
Inlet
Discharge
Recovery Machine
Recovery Cylinder
4
1. Disconnect power.
8. Remove the valve cores.
2. Remove the refrigerant from the existing system per the
manufacturer’s instructions provided with the recovery
system being used. Connect the R-22 gauge set is
connected to both sides of the refrigerant system (as shown),
and verify that the entire system is void of refrigerant in
accordance with the manufacturer’s instructions provided
with the recovery system being used.
A
B
3. Disconnect the liquid and vapor lines from the existing
outdoor unit.
4. Remove the existing outdoor unit.
5. Set the new R-410A outdoor unit and connect the refrigerant
lines. See “Connect Refrigerant Lines” steps 1 through 5. Do
not evacuate the lines.
6. Remove the existing R-22 refrigerant flow control orifice or
thermal expansion valve on the indoor coil, and use a field
provided fitting to reconnect the lines.
Thermal Expansion Valve
A. Suction pressure tap
B. Liquid pressure tap
9. Connect an R-22 cylinder with clean refrigerant to the suction
pressure tap.
10. Connect the R-22 gauge set to the liquid line service valve
and connect a recovery machine with an empty recovery tank
to the gauge set.
A
11. Set the recovery machine for liquid recovery and start the
recovery machine in accordance with the manufacturer’s
instructions provided with the recovery system being used.
12. Open the gauge set valves to allow the recovery machine to
run until a vacuum level less than 0" Hg (gauge pressure) is
established in the existing system line set and indoor coil.
A. Thermal expansion valve
13. Invert the cylinder of clean R-22 and open its valve to allow
liquid refrigerant to flow into the system through the vapor
line valve.
Orifice
A
C
D
14. After all of the liquid refrigerant has been recovered, switch
the recovery machine to vapor recovery to allow the recovery
machine to run until a vacuum level less than 0" Hg (gauge
pressure) is established in the existing system line set and
indoor coil in accordance with the manufacturer’s instructions
provided with the recovery system being used.
E
F
B
G
NOTE: A single system flush should remove all of the mineral oil
from the existing refrigerant lines and indoor coil. A second
flushing may be done (using clean refrigerant) if insufficient
amounts of mineral oil were removed during the first flush. A
second flushing may be required to ensure that the maximum
amount of oil is removed.
A. Distributor fitting
B. Mounting flange
C. Piston orifice
E. Orifice extension stub
F. 0.812" brass hex nut
G. Brass hex fitting
D. Ring seal (supplied)
7. Remove the caps from the suction and liquid pressure taps.
15. Close the valves on the inverted R-22 cylinder and gauge set.
16. Remove the recovery machine, gauges, R-22 cylinder and the
field provided fitting installed in Step 6.
5
17. Install the valve cores.
18. Install the R-410A thermal expansion valve specified for this
system in the indoor coil.
NOTE: R-410A systems use only thermal expansion valves.
19. Pressurize the lines and indoor coil with a pressure not to
exceed 20 psig.
A
B
20. Leak test the lines with a pressure not to exceed 20 psig.
21. Open the suction and liquid service valves fully.
22. Insulate the suction line with refrigerant line insulation
material of ¹⁄₄" or more wall thickness.
23. Pack insulating material around refrigerant lines where they
penetrate the structure to protect the lines and to minimize
vibration transmission.
A. Suction pressure tap
B. Liquid pressure tap
Connect Refrigerant Lines
Refrigerant lines must be connected by a licensed, EPA certified
refrigerant technician in accordance with established procedures.
Thermal Expansion Valve Installation
A
IMPORTANT:
B
I
Connecting refrigerant lines must be clean, dehydrated,
refrigerant-grade copper lines. Heat pumps should be
installed only with specified line sizes for approved system
combinations with elevation differences up to 15 ft and total
length of up to 50 ft. See the Suction Line Sizes and Liquid
Line Sizes charts later in this section.
C
F
I
I
I
Avoid sharp bends or possible kinking in the refrigerant lines
during installation as this may cause a reduction in
performance.
E
D
Use care with the refrigerant lines during the installation
process. Sharp bends or possible kinking in the lines will
cause a reduction in performance.
A. Distributor
D. Liquid line stub
E. Strainer
B. Teflon® seal
C. Thermal expansion valve
F. Teflon® seal
To avoid contamination of the refrigerant system, do not
remove the caps from the lines or system connection points
until connections are ready to be completed.
To install the thermal expansion valve:
1. Separate the distributor assembly.
Install Thermal Expansion Valve
2. If a piston orifice is installed, remove the piston orifice and old
Teflon® seal and discard.
W4GH6 heat pumps are designed for use with thermal expansion
valve systems only. An R-410A system will not operate properly
with an R-22 thermal expansion valve.
3. Insert nozzle end of the thermal expansion valve along with a
new Teflon® seal into the distributor.
4. Tighten to 20 to 30 ft lbs. Use backup wrench on all wrench
Thermal expansion valves equipped with Chatleff-type fittings are
available from the manufacturer. See Thermal Expansion Valve
Kits chart in “System Requirements.”
flats.
NOTE: Overtightening may crush the Teflon® seal and cause
a leak.
5. Attach liquid line portion of distributor assembly along with
new Teflon® seal to the inlet of the thermal expansion valve.
®Teflon is a registered trademark of E.I. Dupont de Nemours and
Company.
6
6. Tighten to 20 to 30 ft lbs. Use backup wrench on all wrench
6. Make sure indoor coil has been put in place according to the
Installation Instructions and is connected to the refrigerant
lines.
flats.
NOTE: Overtightening may crush the Teflon® seal and cause
a leak.
7. Replace valve cores.
8. Pressurize the lines and indoor coil with a pressure not to
7. Connect the external equalizer line to the equalizer port on
exceed 20 psig.
the suction line.
9. Leak test the lines with a pressure not to exceed 20 psig.
8. Tighten to 8 ft lbs.
10. Evacuate the indoor coil and lines to a minimum of
500 microns to remove contamination and moisture, then
disconnect the vacuum pump.
9. Attach the superheat sensing bulb to the suction header with
the strap provided with the thermal expansion valve.
B
A
11. Open the suction and liquid service valves fully.
12. Insulate the suction line with refrigerant line insulation
material of ¹⁄₄" or more wall thickness.
F
E
13. Pack insulating material around refrigerant lines where they
penetrate the structure to protect the lines and to minimize
vibration transmission.
C
Refrigerant Charge
Refrigerant lines must be connected by a licensed, EPA certified
refrigerant technician in accordance with established procedures.
D
IMPORTANT:
I
Refrigerant charge adjustment will be required for line set
lengths greater than 15 ft and for evaporator coils not
matched to the systems.
I
The heat pump is factory charged with the proper refrigerant
charge amount for a matching evaporator and 15 ft of
refrigerant line. Refer to the heat pump rating plate for the
exact amount of this factory charge.
A. Equalizer port
D. Liquid line
B. Superheat sensing bulb
C. Thermal expansion valve
E. Suction line
F. Equalizer line
I
Adjustment of the refrigerant charge will be necessary based
on the system combination and line length. To adjust the
refrigerant size for increased line lengths, add the following
amount of refrigerant.
NOTE: If installing a thermal expansion valve on an indoor coil
that previously used a fixed orifice, be sure to remove the existing
fixed orifice. Failure to remove a fixed orifice when installing a
thermal expansion valve to the indoor coil may result in improper
operation and damage to the system.
For line set lengths greater than 15 ft, add refrigerant by
weighing in 0.60 oz per ft of ³⁄₈" O.D. liquid line.
I
I
If necessary, adjust the refrigerant charge for compatibility
with the evaporator coil.
Connect Liquid and Suction Lines
In heat pump systems, horizontal suction lines should be
slightly sloped toward the heat pump. Piping must avoid dips
or low spots, which can collect oil.
1. Route the suction and liquid lines from the fittings on the
indoor coil to the fittings on the heat pump. Run the lines in
as direct a path as possible, avoiding unnecessary turns and
bends.
Check Charge Using Normal Operating Pressures
Use Normal Operating Pressures chart to perform maintenance
checks.
2. For product efficiency, be sure that the suction line is
insulated over the entire exposed length and that both
suction and liquid lines are not in direct contact with floors,
walls, ductwork, floor joists, or other piping.
NOTES:
I
I
I
The Normal Operating Pressures chart is not a procedure for
charging the system.
3. Remove valve cores.
4. Wrap the service valves with a wet rag.
Minor variations in these pressures may be due to differences
in installations.
5. Connect the suction and liquid lines, using a brazing
compound. Braze with an alloy of silver or copper and
phosphorus with a melting point above 1,100°F.
Significant deviations could mean that the system is not
properly charged or that a problem exists with some
component in the system.
NOTE: Do not use soft solder.
7
Normal Operating Pressures
NOTE: Values provided in chart are typical pressures. Indoor unit matchup, indoor air quality and indoor load will cause pressures to
vary.
Model
-24
-36
-48
-60
Temperature of the Air
Entering the Outdoor Coil
Liquid
Suction
Liquid
Suction
Liquid
Suction
Liquid
Suction
Cooling—1st Stage (Low Capacity)
65ºF
75ºF
85ºF
95ºF
105ºF
115ºF
232
264
307
353
403
460
146
148
149
151
153
155
225
261
302
349
397
461
144
147
149
151
153
157
235
268
310
356
407
466
144
145
147
148
150
152
225
264
305
352
405
459
138
141
142
146
148
150
Cooling—2nd Stage (High Capacity)
65ºF
75ºF
85ºF
95ºF
105ºF
115ºF
240
279
322
371
423
485
143
145
147
149
151
154
239
278
322
367
426
489
139
141
143
146
148
151
244
283
326
374
427
491
140
141
144
147
148
151
241
280
324
373
425
486
134
136
137
138
142
146
Heating—1st Stage (Low Capacity)
40ºF
50ºF
337
322
93
328
333
98
369
366
75
351
335
63
92
117
118
114
Heating—2nd Stage (High Capacity)
20º
279
288
302
306
62
296
309
322
336
62
311
334
354
381
58
308
323
318
329
59
70
69
82
30ºF
40ºF
50ºF
76
75
72
93
92
89
112
113
108
8
Suction Line Sizes
Installations exceeding 100 ft are not recommended.
Liquid Line Sizes
Installations exceeding 100 ft are not recommended.
Btu/h
Line Set Size (in. OD)
Btu/h
Line Set Size (in. OD)
24,000
³⁄₄
³⁄₄
³⁄₄
24,000
³⁄₈
³⁄₈
³⁄₈
³⁄₈
³⁄₈
³⁄₈
³⁄₈
³⁄₈
³⁄₈
36,000
⁷⁄₈
⁷⁄₈
⁷⁄₈
36,000
³⁄₈
48,000
⁷⁄₈
⁷⁄₈
⁷⁄₈
48,000
³⁄₈
60,000
1¹⁄₈
1¹⁄₈
25 ft
1¹⁄₈
60,000
³⁄₈
Line Set Length
Less than
25 ft
Over 25 ft and
up to 50 ft
Line Set Length
Less than
25 ft
25 ft
Over 25 ft and
up to 50 ft
Make Electrical Connections
I
Install an adequately-sized branch circuit disconnect,
according to the NEC, within sight of and readily accessible
from heat pump.
WARNING
I
The cable or conduit and fittings connected from the
disconnect to the heat pump shall be rated for outdoor use.
Single Phase Electrical Connections
Refer to “Wiring Diagram—Single Phase 208/230 Volt.”
Electrical Shock Hazard
Electrically ground condensing unit or heat pump.
Connect ground wire to ground lug.
WARNING
Use copper wire for supply connection.
Correct wire gauge is shown in the chart below.
Failure to follow these instructions can result in
death or electrical shock.
Electrical Shock Hazard
Disconnect power before servicing.
Rating Plate Ampacity
Less than 15
16 - 20
AWG
14
Replace all parts and panels before operating.
Failure to do so can result in death or electrical shock.
12
21 - 30
10
1. Disconnect power.
2. Remove control box cover.
31 - 50
8
3. Connect the field supply wires L1 and L2 to contactor
terminals L1 and L2.
IMPORTANT:
I
Electrical wiring, disconnect means and over-current
protection are to be supplied by the installer. Refer to the
rating plate for the maximum over-current protection,
minimum circuit ampacity, and operating voltage. See wiring
diagrams later in this section.
9
4. Connect ground wire to ground lug.
5. Connect low voltage circuit.
Typical Wiring Connection (low voltage circuit)
T2
T1
NOTE: Some connections may not apply.
Refer to specific thermostat and indoor unit.
Without Auxiliary Heat
Indoor Unit
Thermostat
Outdoor Unit
Power
Power
A
B
R
C
R
C
R
C
L2
L1
Common
1st Stage
Aux. Heat
1st Stage
Aux. Heat
W1
W1
W2
W3
W1
Indoor Blower
If Applicable
G
O
G
A
B
Reversing Valve
L2
L1
O
Y1
Y2
Y1
Y2
Y1
Y2
Compressor
C
A. Ground lug
B. Field supply ground wire
C. 208/230 volt field supply wires
With Auxiliary Heat
Indoor Unit
Thermostat
Outdoor Unit
Power
Power
A
B
R
C
R
C
R
C
Common
Emergency
Heat Relay
Emergency Heat
E
Outdoor
1st Stage
Aux. Heat
Thermostat
W1
W2
W3
W1
W1
1st Stage Aux. Heat
Indoor Blower
G
O
G
If Applicable
Reversing Valve
O
Y1
Y1
Y1
Y2
Compressor
Y2
Y2
A. Do not connect C (common) connection between indoor unit and
thermostat except when required by the indoor thermostat. Refer
to the thermostat installation instructions.
B. C (common) connection between indoor unit and outdoor unit
required for proper operation.
6. Replace control box cover.
7. Reconnect power.
10
Outdoor Unit Typical Wiring Diagram
LT BU
R
Outdoor
Fan
Dual Capacitor
PR
F
C
H
Thermostat
Y1 Y2
W1
BK
C
R
O
Fan
BK
OR
W1
O-OUT
LO-PS
W1
C
L
Y
C
L
BU
L
24V
R
O
R
O
Y1
DF
Common
BK
R
C
S
Y1 OUT
Y1
HI-PS
Compressor
Crankcase Heater
Diagnostic
Module
Defrost
Control
Y
L2
L1
208-230/60/1
Ground
Lug
Ground
Crankcase
Thermostat
Thermostat
Defrost Control
Fan
Reversing Valve
C
R
W1
O
Y1 Y2
Defrost
Thermostat
L1
O-OUT
LO-PS
W1
C
Low Pressure
Switch
L
24V
Compressor
L
R
O
Defrost Switch
BU
DF
Common
BK
L1
C
S
R
Compressor
Contactor
Y1
Y1 OUT
HI-PS
Compressor
Contactor
Diagnostic
Module
Y2
R
L
Y1
C
208-230/60/1
High Pressure
Y
R
Switch
R
Y
L2
LT BU
OR
Crankcaser
Heater
Fan
BK
Defrost Control
F
HI-PS
LO-PS
Crankcase
Thermostat
H
C
Dual
Equipment
Ground
Outdoor Fan
Motor
Low Pressure
Switch
High Pressure
Switch
Capacitor
PR
Line Voltage Factory Installed
Line Voltage Field Installed
24 Volt Factory Installed
Class II Voltage Field Installed
Complete Installation
1. Operate the heat pump for a period of at least 15 minutes to
2. If heat pump does not appear to be functioning correctly,
have heat pump checked by a person certified by the EPA to
handle refrigerant.
allow for pressures and temperatures to stabilize.
11
SEQUENCE OF OPERATION
Defrost Control
Cooling Cycle
Upon cooling demand, the thermostat closes circuit R to O and Y.
Closing R to O and Y energizes the reversing valve for cooling
operation and closes the heat pump contactor, starting the
compressor and outdoor fan. The thermostat automatically
closes R to G circuit, which also brings on the indoor fan at the
same time. Upon satisfying cooling demand, the thermostat will
open the above circuits and open the main contactor, stopping
the compressor and outdoor fan. If the indoor unit is equipped
with a delay timer, the blower will continue to operate for 60 to
90 seconds, which improves system efficiency.
The defrost control board includes the combined functions of the
time/temperature defrost control, defrost relay, diagnostic LEDs
and terminal strip for field wiring connections. See “Defrost
Control Board” in the “Adjust Defrost System” section.
The control provides automatic switching from normal heating
operation to defrost mode and back. During compressor cycle
(call for defrost), the control accumulates compressor run times
at 30, 60 or 90 minute field-adjustable intervals. If the defrost
thermostat is closed when the selected compressor run time
interval ends, the defrost relay is energized and defrost begins.
Heating Cycle
Defrost Control Timing Pins
Upon heating demand, the thermostat closes circuit R to Y, which
closes the heat pump contactor, starting the compressor and
outdoor fan. The reversing valve is not energized in the heating
mode. The thermostat again automatically brings on the indoor
fan at the same time. Upon satisfying heating demand, the
thermostat opens the above circuits and stops heat pump
operation.
Each timing pin selection provides a different accumulated
compressor run time period during one thermostat run cycle. This
time period must occur before a defrost cycle is initiated. The
defrost interval can be adjusted to 30 (T1), 60 (T2) or 90 (T3)
minutes. See “Defrost Control Board” in the “Adjust Defrost
System” section. The defrost timing jumper is factory-installed to
provide a 60-minute defrost interval. If the timing selector jumper
is not in place, the control defaults to a 90-minute defrost
interval. The maximum defrost period is 14 minutes and cannot
be adjusted.
Defrost Cycle
If the outdoor ambient conditions are such that frost forms on the
outdoor coil, the defrost control monitors a defrost cycle. It then
runs the defrost cycle as ambient temperatures require.
A test option is provided for troubleshooting. The test mode may
be started any time the unit is in the heating mode and the
defrost thermostat is closed or jumpered. If the jumper is in the
test position at power-up, the control will ignore the test pins.
When the jumper is placed across the Test pins for 2 seconds,
the control will enter the defrost mode. If the jumper is removed
before an additional 5-second period has elapsed (7 seconds
total), the unit will remain in defrost mode until the defrost
thermostat opens or 14 minutes have passed. If the jumper is not
removed until after the additional 5-second period has elapsed,
the defrost will terminate and the test option will not function
again until the jumper is removed and re-applied.
The defrost control is time/temperature initiated and temperature
terminated with a maximum defrost time (time-out) of 10 minutes.
The time between defrost cycles is preset at 60-minute intervals
at the factory, but can be field adjusted between 30, 60, or
90 minutes. To adjust the time period between defrost cycles,
see “Adjust Time Between Defrost Cycles.”
The defrost control will initiate a defrost cycle when the selected
time period has elapsed and the defrost sensor sees a
temperature below freezing. At the start of a defrost cycle, the
defrost control will energize the reversing valve solenoid, shifting
the reversing valve and de-energizing the outdoor fan. The
defrost relay will also close, energizing temporary heat for
increased comfort during defrost (if the indoor unit is so
equipped). The heat pump will remain in defrost until the defrost
sensor has determined that the frost has been removed from the
coil or a 10-minute period has elapsed, whichever comes first.
Compressor Delay
The defrost board has a field-selectable function to reduce
occasional sounds that may occur while the heat pump is cycling
in and out of the defrost mode. The compressor will be cycled off
for 30 seconds while going in and out of the defrost mode when
the compressor delay jumper is removed.
Defrost Thermostat
NOTE: The 30-second “off” cycle is not functional when
jumpering the TEST pins.
The defrost thermostat is located on the liquid line between the
check/expansion valve and the distributor. When defrost
thermostat senses 42ºF or cooler, the thermostat contacts close
and send a signal to the defrost control board to start the defrost
timing. It also terminates defrost when the liquid line warms up to
70ºF.
12
Time Delay
Adjust Defrost System
Defrost Control Board
The time delay is 5 minutes long. The delay helps to protect the
compressor from short cycling in case the power to the heat
pump is interrupted or a pressure switch opens. The delay is
bypassed by placing the timer select jumper across the TEST
pins for 0.5 seconds.
Optional high pressure switch connections
NOTE: To add the pressure switch, remove the factory-installed
jumper.
Pressure Switch Circuit
P1
FAN
30
60
90
The defrost control includes LO-PS terminals to connect an
optional low pressure (loss of charge pressure) switch. A high
pressure switch (optional) can be connected to the HI PS
terminals. See “Defrost Control Board” in the “Adjust Defrost
System” section.
A
B
C2
K1 Relay
TEST
DS1
DS2
During a single demand cycle, the defrost control will lock out
the heat pump after the fifth time that the circuit is interrupted by
any pressure switch wired to the control board. In addition,
the diagnostic LEDs will indicate a locked-out pressure switch
after the fifth occurrence of an open pressure switch. See
Defrost Control Board Diagnostic LEDs chart later in this section.
The heat pump will remain locked out until power to the board is
interrupted, then re-established, or until the jumper is applied to
the TEST pins for 0.5 seconds.
H
P5
U2
K2 Relay
C
D
U1
O-OUT
P2
W1
C
L
LO-PS
DF
24V
L
I
E
F
R
NOTE: The defrost control board ignores input from the low
pressure switch terminals during:
C5
O
Y1-OUT
HI-PS
Y1
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TEST mode
K3 Relay
Defrost cycle
G
90-second start-up period
P6
Y1
TST PS DF
C
R
O
First 90 seconds after the reversing valve switches heat/cool
modes
A. Defrost time setting pins
B. Test pins
C. Compressor delay pins
D. Reversing valve
F. Defrost thermostat
G. High pressure switch (optional)
H. Diagnostic LEDs
I. Low voltage terminal strip
connections
NOTE: If the TEST pins are jumpered and the 5-minute delay is
being bypassed, the LO PS terminal signal is not ignored during
the 90-second start-up period.
E. Low pressure switch (optional)
Defrost Control Board Diagnostic LEDs
Green
LED (DS2)
Red LED
(DS1)
Adjust Time Between Defrost Cycles
Mode
No Power to Board
Off
Off
WARNING
Normal Operation/Power to Board Simultaneous Slow Flash
Short Cycle Lockout
Alternating Slow Flash
Low Pressure Switch Fault
Low Pressure Switch Lockout
High Pressure Switch Fault
High Pressure Switch Lockout
Off
Off
Slow Flash
On
Electrical Shock Hazard
Slow Flash Off
On Off
Disconnect power before servicing.
Replace all parts and panels before operating.
Failure to do so can result in death or electrical shock.
1. Disconnect power.
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2. Remove the heater compartment access panel.
3. Connect the test pins on the defrost control using a test
jumper wire.
3. Adjust the time period between defrost cycles by placing the
defrost time plug in the proper position. See “Defrost Control
Board.”
NOTE: If the outdoor temperature is above 32°F, connect the
defrost sensor terminals using a test jumper wire. See
“Defrost Control Board” in the “Adjust Defrost System”
section.
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For 30-minute intervals between defrost cycles, connect
the Defrost Time Setting Plug to the pins corresponding
to 30.
4. Replace control box cover.
5. Reconnect power.
6. Start system in heating operation.
For 60-minute intervals between defrost cycles, connect
the Defrost Time Setting Plug to the pins corresponding
to 60 (this setting is the factory preset setting).
7. Time the defrost test cycle as determined by the chart. After
the corresponding defrost cycle time from the chart below
has elapsed, the reversing valve should shift to defrost mode
and the outdoor fan should stop. After 2 seconds of defrost
operation, the reversing valve should shift back to heating
operation and the outdoor fan should start.
For 90-minute intervals between defrost cycles, connect
the Defrost Time Setting Plug to the pins corresponding
to 90.
4. Replace the heater compartment access panel.
5. Reconnect power.
NOTE: If this procedure is not observed, check the reversing
valve solenoid for correct operation by measuring
temperatures and pressures under heating and cooling
modes. If the reversing valve solenoid operates correctly then
replace the defrost control board. See “Sequence of
Operation.”
Troubleshoot the Defrost System
WARNING
Defrost Control Setting
T1 - 30 minutes
Defrost Test Cycle Time
7 seconds
T2 - 60 minutes
14 seconds
Electrical Shock Hazard
T3 - 90 minutes
21 seconds
Disconnect power before servicing.
8. If an adjustment is required, see “Adjust Time Between
Replace all parts and panels before operating.
Failure to do so can result in death or electrical shock.
Defrost Cycles” in the “Adjust Defrost System” section.
9. Disconnect power.
10. Remove control box cover.
11. Remove jumper from test pins and jumper from defrost
The defrost control is equipped with a set of pins (labeled TEST
on control circuit board) to aid in troubleshooting the defrost
system. Connecting the test pins speeds up the defrost cycle
time by a factor of 256.
sensor terminals, if used.
12. Replace control box cover.
13. Reconnect power.
1. Disconnect power.
2. Remove control box cover.
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TROUBLESHOOTING
Heat Pump Fails to Operate Properly
LED Description
Review “Sequence of Operation” and visually inspect the heat
pump before troubleshooting:
Power LED (Green) indicates voltage is present at the power
connection of the module.
Alert LED (Yellow) communicates an abnormal system condition
through a unique flash code. The Alert LED will flash a number of
times consecutively, pause, and then repeat the process. The
number of consecutive flashes correlates to a particular
abnormal condition.
WARNING
Trip LED (Red) indicates there is a demand signal from the
thermostat but no current to the compressor is detected by the
module. The Trip LED typically indicates the compressor
protector is open or may indicate missing supply power to the
compressor.
Electrical Shock Hazard
Disconnect power before servicing.
Diagnostic LEDs Interpretation
Replace all parts and panels before operating.
Failure to do so can result in death or electrical shock.
When an abnormal system condition occurs, the diagnostic
module displays the appropriate Alert and/or Trip LED. The
yellow Alert LED will flash a number of times consecutively,
pause, and then repeat the process. To identify a flash code
number, count the number of consecutive flashes. Refer to the
Flash Codes chart for information on the flash codes.
System Diagnostic Module
W4GH6 heat pumps contain a diagnostic module for
Every time the module powers up, the last Alert LED flash code
that occurred prior to shutdown is displayed for 60 seconds. The
module will continue to display the previous flash code until the
condition returns to normal or 24 VAC is removed from the
module. Trip and Alert LED’s flashing at the same time means
control circuit voltage is too low for operation.
troubleshooting heat pump system failures. By monitoring and
analyzing data from the compressor and thermostat demand, the
module can accurately detect the cause of electrical and system
related failure without any sensors. If a system problem occurs, a
flashing LED indicator communicates the failure code.
Flash Codes
LED Status
Power (Green)
Trip (Red)
Fault Description
Troubleshooting Information
Module has power.
I
Supply voltage is present at module terminals.
Thermostat demand signal Y1
is present, but the
compressor is not running.
I
I
I
I
I
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Compressor protector is open.
Outdoor unit power disconnect is open.
Compressor circuit breaker or fuse(s) is open.
Broken wire or connector is not making contact.
Low pressure switch is open, if present in system.
Compressor contactor has failed to open.
Alert (Yellow) Flash Code 1
Alert (Yellow) Flash Code 2
Long Run Time: Compressor
is running extremely long run
cycles.
NOTE: Not applicable on heat
pump models.
System Pressure Trip:
Discharge or suction pressure
out of limits or compressor is
overloaded.
I
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High head pressure.
Condenser coil has poor air circulation (dirty, blocked,
damaged).
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Condenser fan is not running.
Return air duct has substantial leakage.
If low pressure switch is present in the system, go to Flash Code
1 information.
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Flash Codes
LED Status
Fault Description
Troubleshooting Information
Alert (Yellow) Flash Code 3
Short Cycling: Compressor is
running only briefly.
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Thermostat demand signal is intermittent.
Time delay relay or control board is defective.
If high pressure switch is present, go to Flash Code
2 information.
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If low pressure switch is present, go to Flash Code
1 information.
Alert (Yellow) Flash Code 4
Alert (Yellow) Flash Code 5
Locked Rotor
Open circuit
I
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Run capacitor has failed.
Low line voltage (contact utility if voltage at disconnect is low).
Excessive liquid refrigerant in the compressor.
Compressor bearings are seized.
I
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Outdoor unit power disconnect is open.
Compressor circuit breaker or fuse(s) is open.
Compressor contactor has failed to open.
High pressure switch is open and requires manual reset.
Open circuit in the compressor supply wiring or connections.
Unusually long compressor protector reset time due to the
extreme ambient temperature.
I
Compressor windings are damaged.
Alert (Yellow) Flash Code 6
Alert (Yellow) Flash Code 7
Open Start Circuit: Current
only in run circuit.
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Run capacitor has failed.
Open circuit in the compressor start wiring or connections.
Compressor start winding is damaged.
Open Run Circuit: Current
only in start circuit
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Open circuit in the compressor run wiring or connections.
Compressor run winding is damaged.
NOTE: This code will
flash within 5 minutes of
power interruption until the
5 minute short cycle timer
has elapsed. Allow at least
5 minutes of run time before
confirming this code.
Alert (Yellow) Flash Code 8
Welded Contactor:
Compressor always runs.
I
I
Compressor contactor has failed to close.
Thermostat demand signal not connected to the module.
Alert (Yellow) Flash Code 9
Low Voltage: Control circuit
less than 17 VAC
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Control circuit transformer is overloaded.
Low line voltage (contact utility if voltage at disconnect is low).
24 VAC Power Wiring
Thermostat Demand Wiring
The diagnostic module requires a constant nominal 24 VAC
power supply. The wiring to the module’s R and C terminals must
be directly from the indoor unit or thermostat. The module cannot
be powered by R and C terminals on the defrost board without
experiencing nuisance alerts.
The diagnostic module requires a thermostat demand signal to
operate properly. The thermostat demand signal input, labeled Y
on the module, should always be connected to the compressor
contactor coil so that when the coil is energized, the demand
signal input is 24 VAC. When the coil is not energized, the
demand signal input should be less than 0.5 VAC.
16
Incorrectly Wired Module Codes
Depending on the system configuration, some Alert flash codes
may not be active. The presence of safety switches affects how
the system alerts are displayed by the module.
Incorrectly wiring the diagnostic module will cause false LED
codes. The Incorrectly Wired Module Troubleshooting chart
describes LED operation when the module is incorrectly wired
and what troubleshooting action is required to correct the
problem.
Incorrectly Wired Module Troubleshooting
Incorrectly Wired Module Indication
Recommended Troubleshooting Action
Green LED is not on, module does not
power up.
Determine if both R and C module terminals are connected. See “24 VAC Power
Wiring” section for R and C wiring.
Green LED intermittent, module powers
up only when the compressor runs.
Determine if R and Y terminals are wired in reverse. See “24 VAC Power Wiring” earlier
in this section for R and C wiring.
Trip LED is on but the system and the
compressor check OK.
Verify that the Y terminal is connected to the 24 VAC at the contactor coil.
Trip LED and Alert LED are flashing
together.
Verify that the R and C terminals are connected. See “24 VAC Power Wiring” earlier in
this section for R and C wiring.
Alert Flash Code 3 (Compressor Short
Cycling) is displayed incorrectly.
Verify that the Y terminal is connect to the 24 VAC at the contactor coil.
Alert Flash Codes 5, 6 or 7 (Open Circuit,
Open Start Circuit or Open Run Circuit)
are displayed incorrectly.
Check that the compressor run and start wires are through the module’s current
sensing holes. Verify that the Y terminal is connected to the 24 VAC at the contactor
coil.
Alert Flash Code 6 (Open Start Circuit) is
displayed for Code 7 (Open Run Circuit) or
vice versa.
Check that the compressor run and start wires are routed through the correct module
sensing holes.
Alert Flash Code 8 (Welded Contactor) is
displayed incorrectly.
Determine if the module’s Y terminal is connected. Verify that the Y terminal is
connected to the 24 VAC at the contactor coil.
SYSTEM MAINTENANCE
ASSISTANCE OR SERVICE
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Leaves and other large obstructions should be removed from
the heat pump surfaces without damaging the fin surface of
the coil.
If you need further assistance, you can write to the below
address with any questions or concerns:
Whirlpool® Home Cooling and Heating
14610 Breakers Drive
Jacksonville, FL 32258
Routinely clean or change the indoor air filter. Should the
indoor coil become dirty, thus restricting airflow, call a
qualified service person to clean the coil surface.
Please include a daytime phone number in your correspondence.
An annual inspection by a qualified person should be
performed to ensure continued quality performance.
Accessories
To order accessories contact your Whirlpool® Home Cooling and
Heating dealer.
17
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Keep this book and your sales slip together for future
reference. You must provide proof of purchase or installation
date for in-warranty service.
Write down the following information about your Split System
Heat Pump—Outdoor Section to better help you obtain
assistance or service if you ever need it.
Dealer name____________________________________________________
Address________________________________________________________
Phone number__________________________________________________
Model number __________________________________________________
Serial number __________________________________________________
Installation date ________________________________________________
19
48488A006
®Registered Trademark/TM Trademark of Whirlpool, U.S.A.,
Manufactured under license by Tradewinds Distributing Company, LLC., Coconut Grove, Florida
6/06
Printed in U.S.A.
© 2006. All rights reserved.
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