LENNOX Air Conditioner/heat Pump(outside Unit) Manual L0806495
User Manual: LENNOX LENNOX Air conditioner/heat pump(outside unit) Manual LENNOX Air conditioner/heat pump(outside unit) Owner's Manual, LENNOX Air conditioner/heat pump(outside unit) installation guides
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LENNOX
';_2002 Lennox Industries inc.
Dallas, Texas
INSTALLATION
INSTRUCTIONS
HPXA12 SERIES UNITS
HEAT PUMP UNITS
504,777M _ Technical
05/04 IlI_.LU_Publications
Supersedes 02/04 Lithe U.S.A.
HPXA12 Elite®outdoor units use R410A, which is an ozone
friendly HFC refrigerant, This unit must be installed with a
matching indoor blower coil and line set as outlined in the
Lennox Engineering Handbook. HPXA12 outdoor units are
designed for use in expansion valve systems only. They
are not designed to be used with other refrigerant flow con-
trol devices, An expansion valve approved for use with
R410A must be ordered separately and must be installed
prior to operating the unit,
,&IMPORTANT
HPXA12 Outdoor Unit ........................... 1
Shipping & Packing List ......................... 1
General Information ............................. 1
Unit Dimensions ................................ 2
Setting the Unit ................................. 3
Electrical ...................................... 4
Refrigerant Piping .............................. 5
Flushing Existing Line Set & Indoor Coil ........... 6
Refrigerant Metering Device ..................... 7
Manifold Gauge Set ............................. 8
Service Valves ................................. 8
Leak Testing ................................... 9
Evacuation ................................... 10
Start-Up ...................................... 11
Charging .................................... 11
System Operation ............................. 14
Defrost System ............................... 15
Maintenance .................................. 18
Optional Accessories .......................... 18
Homeowner Information ........................ 18
HPXA12 Check List ............................ 20
RETAIN THESE INSTRUCTIONS
FOR FUTURE REFERENCE
These instructions are intended as a general guide and do
not supersede local codes in any way, Consult authorities
having jurisdiction before installation.
1 - Assembled HPXA12 outdoor unit
Check the unit components for shipping damage. Ifyou find
any damage, immediately contact the last carrier,
,&IMPORTANT
WARNING
,&WARNING
05/04
IIIHIIIIIIIIIIIIIflll,lll,llllllf 504,777M
IIIHIIIIIIII,III,III,III,III,IIIIIIIIIIIII
INLET
©
AIR
INLET_N 7AIR
INLET'_ AIR
Top View
INLET
©
AIR
VAPOR LINE
CONNECTION
LIQUID LINE
CONNECTION
Model No.
HPXA12-018 in.
HPXA12-024
HPXA12-030
HPXA12-036 mm
HPXA12-042
HPXA12-048 in.
HPXA12-060 mm
A
24-1/4
616
28-1/4
718
B
33-1/4
845
37-1/4
946
C
32-1/2
826
36-1/2
927
A h..J
IIC B
Side View
_" ELECTRICAL
INLETS
OUTDOOR
COIL FAN
COMPRESSOR_
VAPOR &
LIQUID LINE
CONNECTION
2-3/4 (70)
3/74, '_
OPTIONAL UNIT
(19) STAND-OFFKIT
(Field Installed)
Side View
Page 2
&CAUTION
&CAUTION
Outdoor units operate under a wide range of weather con-
ditions; therefore, several factors must be considered
when positioning the outdoor unit. Unit must be positioned
to give adequate clearances for sufficient airflow and servi-
cing. A minimum clearance of 24 inches (610 mm) between
multiple units must be maintained. Refer to figure 1 for
installation clearances.
Installation Clearances
*NO TE -A service clearance of 30" (762 mm) must be main-
tained on one of the sides adjacent to the control box. Clear-
ance to one of the other three sides must be 36" (914 mm).
Clearance to one of the remaining two sides may be 12" (305
mm) and the final side may be 6" (152 mm).
NOTE -A clearance of 24" (610 mm) must be maintained
between two units.
NOTE -48" (1219 mm) clearance required on top
of unit. Maximum soffit overhang is 36" (914 mm).
Figure 1
1 - Place a sound-absorbing material, such as Isomode,
under the unit if it will be installed in a location or posi-
tion that will transmit sound or vibration to the living
area or adjacent buildings.
2 - Mount unit high enough above ground or roof to allow
adequate drainage of defrost water and prevent ice
build-up.
3 - In heavy snow areas, do not locate unit where drifting
will occur. The unit base should be elevated above the
depth of average snows.
NOTE- Elevation of the unit may be accomplished by
constructing a frame using suitable materials. Ira sup-
port frame is constructed, it must not block drain holes
in unit base.
4 - When installed in areas where low ambient tempera-
tures exist, locate unit so winter prevailing winds do not
blow directly into outdoor coil.
5 - Locate unit away from overhanging roof lines which
would allow water or ice to drop on, or in front of, coil or
into unit.
Slab Mounting-Figure 2
When installing the unit at grade level, the top of the slab
should be high enough above the grade so that water from
higher ground will not collect around the unit. See figure 2.
The slab should have a slope tolerance away from the
building of 2 degrees or 2 inches per 5 feet (51 mm per
1524 mm). This will prevent ice build-up under the unit dur-
ing a defrost cycle. Refer to roof mounting section for barri-
er construction if the unit must face prevailing winter winds.
Slab Mounting At Ground Level
STRUCTURE DISCHARGE AIR
0
MOUNTING SLAB MUST SLOPE
AWAY FROM BUILDING.
GROUNDLEVEL
Figure 2
Roof Mounting-Figure 3
Install unit a minimum of 6 inches (152 mm) above the roof
surface to avoid ice build-up around the unit. Locate the
unit above a load bearing wall or area of the roof that can
adequately support the unit, Consult local codes for rooftop
applications.
Rooftop Application
Wind Barrier Construction
PREVAILING WINTER WINDS
<?
I WINDBARRIER I
INLET AIR
INLET AIR
0
INLET AIR
Figure 3
INLET AIR
0
Page 3
Ifunitcoilcannotbemountedawayfromprevailingwinter
winds,constructa windbarrier.Sizebarrierat leastthe
sameheightandwidthastheoutdoorunit,Mountbarrier24
inches(610mm)fromthesidesoftheunitinthedirectionof
prevailingwinds.
IntheU,S,A.,wiringmustconformwithcurrentlocalcodes
andthecurrentNationalElectricCode(NEC).In Canada,
wiringmustconformwithcurrentlocalcodesandthecurrent
CanadianElectricalCode(CEC).
Refertothefurnaceorblowercoilinstallationinstructions
foradditionalwiringapplicationdiagramsandrefertounit
nameplatefor minimumcircuitampacityand maximum
overcurrentprotectionsize.
WARNING
1 - Install line voltage power supply to unit from a properly
sized disconnect switch,
2 - Ground unit at unit disconnect switch or to an earth
ground,
NOTE -To facilitate conduit, a hole is in the bottom of
the control box, Connect conduit to the control box us
ing a proper conduit fitting,
NO TE -Units are approved for use only with copper
conductors,
Refer to figure 4 for high voltage field wiring diagram.
NOTE -A complete unit wiring diagram is located in
side the unit control box cover,
3 - Install room thermostat (ordered separately) on an in-
side wall approximately in the center of the conditioned
area and 5 feet (1.5 m) from the floor. It should not be
installed on an outside wall or where it can be effected
by sunlight, drafts or vibrations,
4 - Install low voltage wiring from outdoor to indoor unit
and from thermostat to indoor unit. See figures 5 and 6.
NOTE - 24V, Class II circuit connections are made in
the low voltage junction box,
Typical Field Wiring Diagram
B4
OUTDOOR
FAN
KSI
POTENTIAL RELAY
GND.LUG
NOTE-
/_kFOR USE WITH COPPER CONDUCTORS
ONLY,REFER TO UNIT RATING
PLATE FOR MINIMUM CIRCUIT
AMPADITY AND MAXIMUM OVER-
CURRENT PROTECTION SIZE
/_ WARNING-
ELECTRIC SHOCK HAZARD,CAN CAUSE INJURY
OR DEATH.UNIT MUST BE GROUNDED IN
ACCORDANCE WITH NATIONAL AND LOCAL CODES.
START
CAPACITOR
(_ D12
@ DUAL
CAPACITOR
AI08
DEFROST CONTROL
_FAN_
cc
Y l OUT
my
HI -PS
AMBO T
o L
o C
_RV WI I
O-OUT
L
Figure 4
208-230/60/I
m. L2 Z_
DLLI
IGROUND
T
Page 4
HPXA12 and Blower Unit
Thermostat Designations
(Some connections may not apply.
Refer to specific thermostat and indoor unit.)
Thermostat Indoor Outdoor
Unit Unit
®4
(b+
@+
power __
common _(__
1st. stage aux. heat @
indoor blower -@
reversing valve
power
common
1st. stage aux. hea_t
compressor
®
J
Figure 5
Outdoor Unit and Blower Unit
Thermostat Designations
(with auxiliary heat)
(Some connections may not apply.
Refer to specific thermostat and indoor unit.)
Thermostat
®
Q
_)-
®
®
G
power 1_
common I
emergency heat I -
I
I
1st. stage aux. 7T&aq-
L
indoor blower
reversinq.vatve
Indoor
Unit
__. power
he_m "_"e_ rnat _lyj_
1sTst_-g _. _at
@1
®1
compressor
Outdoor
Unit
®1
©1
®1
®1
®1
Figure 6
If the HPXA12 unit is being installed with a new indoor coil
and line set, the plumbing connections should be made as
outlined in this section. If an existing line set and/or indoor
coil is going to be used to complete the HPXA12 system,
refer to the following section that includes flushing proce-
dures.
Field refrigerant piping consists of liquid and vapor lines
from the outdoor unit (sweat connections) to the indoor coil
(flare or sweat connections). Use Lennox L15 (sweat, non-
flare) series line sets as shown in table 1 or use field-fabri-
cated refrigerant lines, Refer to Refrigerant Piping Guide
(Corp, 9351-L9) for proper size, type, and application of
field-fabricated lines, Valve sizes are also listed in table 1.
Plumbing Connections
HPXA12 Matched with New Indoor Coil and Line Set
If you are replacing an existing coil that is equipped
with a liquid line functioning as a metering orifice, re-
place the liquid line prior to installing the HPXA12 unit.
See table 1.
Table 1
Refrigerant Line Sets
Valve Field Size Recommended Line Set
Connections
Model L15
Liquid Vapor Liquid Vapor Line Sets
Line Line Line Line
-18 3/8 in, 3/4 in, 3/8 in. 3/4 in. L15-41
-24 (10 ram) (19 ram) (10 ram) (19 ram) 15 ft. - 50 ft.
-30 (4.6 m - 15 m)
-36 3/8 in, 7/8 in, 3/8 in. 7/8 in. L15-65
-42 (10 mm) (22 ram) (10 ram) (22 ram) 15 ft. - 50 ft.
-48 (4.6 m - 15 m)
3/8 in. 1-1/8 in. 3/8 in. 1-1/8 in, Field
-60 (10 ram) (29 ram) (10 ram) (29 ram) Fabricated
NOTE -Units are designed for line sets of up to fifty feet
(15m).
Installing Refrigerant Line
During the installation of any heat pump or a/c system, it is
important to properly isolate the refrigerant lines to prevent
unnecessary vibration, Line set contact with the structure
(wall, ceiling or floor) causes some objectionable noise
when vibration is translated into sound, As a result, more
energy or vibration can be expected, Closer attention to
line set isolation must be observed,
Following are some points to consider when placing and
installing a high-efficiency outdoor unit:
1-Placement - Be aware some localities are adopting
sound ordinances based on how noisy the unit is from
the adjacent property not at the original installation.
Install the unit as far as possible from the property line,
When possible, do not install the unit directly outside a
window, Glass has a very high level of sound transmis-
sion.
2- Line Set Isolation - The following illustrations demon-
strate procedures which ensure proper refrigerant line
set isolation. Figure 7 shows how to install line sets on
vertical runs. Figure 8 shows how to install line sets on
horizontal runs, Figure 9 shows how to make a transition
from horizontal to vertical. Finally, figure 10 shows how
to place the outdoor unit and line set,
Page 5
Refrigerant Line Sets
How To Install Vertical Runs
(new construction shown)
NOTE -Similar installation practices should be used if
line set is to be installed on exterior of outside waft.
i
Outside Wall
\
Wood Block
r
Between Studs
UquidLin2
Vapor Line
(wrapped with
Outside Wall
_Caulk
PVC Pipe Fiberglass
Insulation
IMPORTANT- Refrigerant
lines must not contact j
structure, j
IMPORTANT- Refrigerant
lines must not contact wall. Vapor Line Liquid Line
Wire Tie
\ Inside Wall
\ Strap
_ Sleeve
_- Wire Tie
--_------- Wood Block
_-.-------- Wire Tie
Strap
\_ Sleeve
Figure 7
Page 6
Refrigerant Line Sets:
Installing Horizontal Runs
To hang line set from joist or rafter,
use either metal strapping material
or anchored heavy nylon wire ties.
8 feet
Floor Joist or
Roof Rafter
/
/
I
I
8 feet
Wire Tie
(around vapor line only)
Tape or Wire Tie
Strapping Material (around vapor line only)
\
Tape or Wire Tie
Metal Sleeve
/
jr _ _ Floor: Joist or: Roof Rafter)
8
Strap the vapor line to the joist or rafter at 8 ft.
intervals then strap the liquid line to the vapor line.
Figure 8
Page 7
AnchoredHeavy
NylonWireTie
Refrigerant Line Sets:
Transition From Vertical To Horizontal
Automotive
Muffler-Type
Hanger
Wall
Stud Strap Liquid Line
To Vapor Line
Wall
Stud
Strap Liquid Line
To Vapor Line
Liquid Line
Metal
Sleeve
Vapor Line
Wrapped in
Armaflex Liquid Line
Figure 9
Metal
Sleeve
Vapor Line
Wrapped in
Armaflex
Outside Unit Placement and Installation
Install unit away from windows.
Two 90° elbows
installed in line set
will reduce line set
vibration.
Figure 10
Page 8
AWARNING AIMPORTANT
Brazing Connection Procedure
1 - Cut ends of the refrigerant lines square (free from nicks
or dents), Debur the ends, The pipe must remain
round, do not pinch end of the line,
2 - Before making line set connections, use dry nitrogen to
purge the refrigerant piping. This will help to prevent
oxidation and the introduction of moisture into the sys-
tem,
3 - Use silver alloy brazing rods (5 or 6 percent minimum
silver alloy for copper-to-copper brazing or 45 percent
silver alloy for copper-to-brass or copper-to-steel braz-
ing) which are rated for use with R410A refrigerant,
Wrap a wet cloth around the valve body and the copper
tube stub. Remove light maroon washers from service
valves and shield light maroon stickers in order to pro-
tect them during brazing, Braze the line set to the ser-
vice valve,
4 - Wrap a wet cloth around the valve body and copper
tube stub to protect it from heat damage during braz-
ing, Wrap another wet cloth underneath the valve body
to protect the base paint,
NOTE -The tube end must stay bottomed in the fitting
during final assembly to ensure proper seating, sealing
and rigidity.
5- Install a field-provided thermal expansion valve (ap-
proved for use with R410A refrigerant) in the liquid line
at the indoor coil.
AWARNING
_&CAUTION
Required Equipment
You will need the following equipment in order to flush the
existing line set and indoor coil: two clean R22 recovery
bottles, an oilless recovery machine with a pump down fea-
ture, and two sets of gauges (one for use with R22 and one
for use with the R410A).
Flushing Procedure
1 - Remove existing R22 refrigerant using the appropri-
ate procedure below.
ff the existing outdoor unit is not equipped with
shut-off valves, or if the unit is not operational
AND you plan to use the existing R22 refrigerant to
flush the system -- Disconnect all power to the exist-
ing outdoor unit. Connect the existing unit, a clean re-
covery cylinder and the recovery machine according
to the instructions provided with the recovery ma-
chine. Remove all R22 refrigerant from the existing
system. Refer to gauges after shutdown to confirm
that the entire system is completely void of refrigerant.
Disconnect the liquid and vapor lines from the existing
outdoor unit.
If the existing outdoor unit is equipped with manu-
al shut-off valves AND you plan to use NEW R22
refrigerant to flush the system -- Start the existing
R22 system in the cooling mode and close the liquid
line valve, Pump all of the existing R22 refrigerant
back into the outdoor unit, (It may be necessary to by-
pass the low pressure switches to ensure complete re-
frigerant evacuation.) When the low side system pres-
sures reach 0 psig, close the vapor line valve. Discon-
nect all power to the existing outdoor unit, Refer to
Page 9
gaugesaftershutdownto confirmthatthevalvesare
notallowingrefrigeranttoflowbackintothelowsideof
thesystem.Disconnecttheliquidandvaporlinesfrom
theexistingoutdoorunit.
2 - Removetheexistingoutdoorunit,SetthenewR410A
unitand followthe brazingconnectionprocedure
whichbeginson thepreviouspageto makelineset
connections,DO NOT install provided R410A
check/expansion valve at this time.
Make low voltage and line voltage connections to the
new outdoor unit. DO NOT turn on power to the unit
or open the outdoor unit service valves at this
time.
3 - Remove the existing refrigerant flow control orifice or
thermal expansion/check valve before continuing with
flushing procedures. The existing devices are not ap-
proved for use with R410A refrigerant and may pre-
vent proper flushing, Use a field-provided fitting to re-
connect the lines.
AIMPORTANT
EXISTING
INDOOR COIL
RECOVERY
CYLINDER
INVERTED R22
CYLINDER
(Contains clean
R22 to be used for
flushing)
EXISTING VAPOR LINE
EXISTING LIQUID LINE
Flushing Connections
SERVICE VALVE
LIQUID LINE !
SERVICE VALVE
TANK RETURN
INLET
DISCHARGE
RECOVERY MACHINE
HPXA12 UNIT
LOW HIGH
PRESSURE PRESSURE
NOTE -The inverted R22 cylin-
der must contain at least the
same amount of refrigerant as
was recovered from the existing
system.
Figure 11
Page 10
4- Removethe pressuretap valve coresfrom the
HPXA12unit'sservicevalves,ConnectanR22cylin-
derwithcleanrefrigeranttothevaporservicevalve.
ConnecttheR22gaugesettotheliquidlinevalveand
connectarecoverymachinewithanemptyrecovery
tanktothegaugeset,
5- Settherecoverymachineforliquidrecoveryandstart
therecoverymachine,Openthegaugesetvalvesto
allowtherecoverymachinetopullavacuumontheex-
istingsystemlinesetandindoorcoil,
6 - InvertthecylinderofcleanR22andopenitsvalveto
allowliquidrefrigeranttoflowintothesystemthrough
thevaporlinevalve,Allowtherefrigerantto passfrom
thecylinderandthroughthelinesetandtheindoorcoil
beforeitenterstherecoverymachine,
7- Afteralloftheliquidrefrigeranthasbeenrecovered,
switchtherecoverymachinetovaporrecoverysothat
alloftheR22vaporisrecovered,Alltherecoveryma-
chinetopullavacuumonthesystem,
NQ TE -A single system flush should remove all of the
mineral oil from the existing refrigerant lines and in-
door coil. A second flushing may be done (using clean
refrigerant) if insufficient amounts of mineral oil were
removed during the first flush. Each time the system
is flushed, you must allow the recovery machine
to pull a vacuum on the system at the end of the
procedure.
8- Close the valve on the inverted R22 drum and the
gauge set valves, Pump the remaining refrigerant out
of the recovery machine and turn the machine off,
9 - Use nitrogen to break the vacuum on the refrigerant
lines and indoor coil before removing the recovery ma-
chine, gauges and R22 refrigerant drum, Reinstall
pressure tap valve cores into HPXA12 service valves,
10-Install the provided check/expansion valve (approved
for use with R410A refrigerant) in the liquid line at the
indoor coil,
HPXA12 units are applicable to check expansion valve
systems only. See indoor coil installation instructions and
the Lennox engineering handbook for approved R410A
TXV match-ups and application information,
NOTE -R410A systems will not operate properly with an
R-22 valve.
Check Expansion Valve Systems
Check expansion valves equipped with either Chatleff or
flare-type fittings are available from Lennox, Refer to the
Engineering Handbook for applicable expansion valves
for use with specific match-ups, See table 2 for applicable
check and expansion valve kits,
If you install a check expansion valve with an indoor coil
that includes a fixed orifice, remove the orifice before
the check expansion valve is installed.
IMPORTANT
Table 2
Indoor Check Expansion Valve Kits
Model Kit Catalog Number
HPXA12-018
HPXA12-024 49L24
HPXA12-030
HPXA12-036
HPXA 12-042
HPXA12-048 49L25
HPXA12-060
See figure 12 for installation of the check expansion valve,
Metering Device Installation
distributor
o-ring
strainer
o-ring
expansion
valve _
liquid line_
stub
Figure 12
Manifold gauge sets used with systems charged with
R410A refrigerant must be capable of handling the higher
system operating pressures. The gauges should be rated
for use with pressures of 0 - 800 on the high side and a low
side d30" vacuum to 250 psi with dampened speed to 500
psi. Gauge hoses must be rated for use at up to 800 psi of
pressure with a 4000 psi burst rating,
The liquid line and vapor line service valves (figures 13 and
14) and gauge ports are used for leak testing, evacuating,
charging and checking charge, See table 3 for torque re-
quirements,
Each valve is equipped with a service port which has a fac-
tory-installed Schrader valve. A service port cap protects
the Schrader valve from contamination and serves as the
primary leak seal,
Page 11
Table 3
Torque Requirements
Part Recommended Torque
Service valve cap 8 ft.- lb. 11 NM
Sheet metal screws 16 in.- lb. 2 NM
Machine screws #10 28 in.-lb. 3 NM
Compressor bolts 90 in.- lb. 10 NM
Gauge port seal cap 8 ft.- lb. 11 NM
IMPORTANT
To Access Schrader Port:
1 - Remove service port cap with an adjustable wrench.
2 - Connect gauge to the service port.
3- When testing is completed, replace service port cap.
Tighten finger tight, then an additional 1/6 turn.
To Open Service Valve:
1 - Remove stem cap using an adjustable wrench,
2 - Use a service wrench with a hex head extension to back
the stem out counterclockwise as far as it will go,
NOTE- Use a 3/16" hex head extension for liquid line
sizes or a 5/16" extension for vapor line sizes,
3- Replace stem cap, and tighten it firmly, Tighten finger
tight, then tighten an additional 1/6 turn.
Service Valve
(Valve Closed)
serviceport _,_m
insert hex
to outdoor coil wrench here
service
port cap
cap
Schrader valve open
to line set when valve is
closed (front seated) (valve front seated)
coil
Service Valve
(Valve Open)
insert hex
wrench here \
service
port
to outdoor coil
stem cap
service port to indoor coil
cap Schrader
valve
Figure 13
Page 12
ToCloseServiceValve:
1- Removestemcapwithanadjustablewrench.
2 - Useaservicewrenchwithahexheadextensiontoturn
thestemclockwisetoseatthevalve,Tightenfirmly,
NOTE -Use a 3/16" hex head extension for liquid line
sizes or a 5/16" extension for vapor line sizes.
3- Replace stem cap. Tighten finger tight, then tighten an
additional 1/6 turn.
Bali-Type Vapor Valve
Vapor line service valves function the same way as the oth-
er valves, the difference is in the construction, These
valves are not rebuildable, If a valve has failed, you must
replace it. A ball valve valve is illustrated in figure 14,
The ball valve is equipped with a service port with a factory-
installed Schrader valve, A service port cap protects the
Schrader valve from contamination and assures a leak-
free seal,
Vapor Line (Ball Type) Service Valve
(Valve Open)
Use adjustable wrench
To open: Rotate stem counter-clockwise 90%
To close: Rotate stem clockwise 90%
to outdoor coil j_ stem cap
ste m
ball
shown open)
to indoor coil
service port
cap service port
Schrader valve
Figure 14
After the line set has been connected to the indoor and
outdoor units, check the line set connections and indoor
unit for leaks,
AWARNING
WARNING
Using an Electronic Leak Detector
1 - Connect a cylinder of R410A to the center port of the
manifold gauge set.
2 - With both manifold valves closed, open the valve on
the R410A cylinder (vapor only),
3 - Open the high pressure side of the manifold to allow
the R410A into the line set and indoor unit, Weigh in a
trace amount of R410A, [A trace amount is a maximum
of 2 ounces (57 g) or 3 pounds (31 kPa) pressure,]
Close the valve on the R410A cylinder and the valve
on the high pressure side of the manifold gauge set,
Disconnect the R410A cylinder.
4 - Connect a cylinder of nitrogen with a pressure regulat-
ing valve to the center port of the manifold gauge set,
5 - Connect the manifold gauge set high pressure hose to
the vapor valve service port. (Normally, the high pres-
sure hose is connected to the liquid line port; however,
connecting it to the vapor port better protects the man-
ifold gauge set from high pressure damage.)
6 - Adjust the nitrogen pressure to 150 psig (1034 kPa),
Open the valve on the high side of the manifold gauge
set which will pressurize line set and indoor unit,
7 - After a few minutes, open a refrigerant port to ensure
the refrigerant you added is adequate to be detected,
(Amounts of refrigerant will vary with line lengths.)
Check all joints for leaks. Purge nitrogen and R410A
mixture, Correct any leaks and recheck.
WARNING ,IMPORTANT
Page 13
Evacuatingthesystemof noncondensablesis criticalfor
properoperationoftheunit.Noncondensablesaredefined
asanygasthatwillnotcondenseundertemperaturesand
pressurespresentduringoperationofanairconditioning
system.Noncondensablesandwatervaporcombinewith
refrigeranttoproducesubstancesthatcorrodecopperpip-
ingandcompressorparts.
IMPORTANT
1 - Connect manifold gauge set to the service valve ports
as follows:
• low pressure gauge to vapor line service valve
• high pressure gauge to liquid line service valve
2 - Connect micron gauge,
3 - Connect the vacuum pump (with vacuum gauge) to the
center port of the manifold gauge set,
4-Open both manifold valves and start the vacuum
pump,
5 - Evacuate the line set and indoor unit to an absolute
pressure of 23,000 microns (29.01 inches of mercu-
ry). During the early stages of evacuation, it is desir-
able to close the manifold gauge valve at least once to
determine if there is a rapid rise in absolute pressure.
A rapid rise in pressure indicates a relatively large leak.
If this occurs, repeat the leak testing procedure,
NOTE -The term absolute pressure means the total
actual pressure within a given volume or system,
above the absolute zero of pressure. Absolute pres-
sure in a vacuum is equal to atmospheric pressure mi-
nus vacuum pressure.
6 - When the absolute pressure reaches 23,000 microns
(29.01 inches of mercury), close the manifold gauge
valves, turn off the vacuum pump and disconnect the
manifold gauge center port hose from vacuum pump.
Attach the manifold center port hose to a nitrogen cylin-
der with pressure regulator set to 150 psig (1034 kPa)
and purge the hose. Open the manifold gauge valves
to break the vacuum in the line set and indoor unit.
Close the manifold gauge valves.
AWARNING
7 - Shut off the nitrogen cylinder and remove the manifold
gauge hose from the cylinder. Open the manifold
gauge valves to release the nitrogen from the line set
and indoor unit.
8 - Reconnect the manifold gauge to the vacuum pump,
turn the pump on, and continue to evacuate the line set
and indoor unit until the absolute pressure does not
rise above 500 microns (29.9 inches of mercury) within
a 20-minute period after shutting off the vacuum pump
and closing the manifold gauge valves.
9 - When the absolute pressure requirement above has
been met, disconnect the manifold hose from the vacu-
um pump and connect it to an upright cylinder dR410A
refrigerant. Open the manifold gauge valves to break
the vacuum from 1 to 2 psig positive pressure in the line
set and indoor unit. Close manifold gauge valves and
shut off the R410A cylinder and remove the manifold
gauge set,
,& IMPORTANT
1 - Rotate fan to check for frozen bearings or binding.
2 - Inspect all factory and field-installed wiring for loose
connections.
3 - After evacuation is complete, open the liquid line and
vapor line service valves (counterclockwise) to release
refrigerant charge (contained in outdoor unit) into the
system.
4 - Replace stem caps and secure finger tight, then tight-
en an additional (1/6) one-sixth of a turn.
5- Check voltage supply at the disconnect switch. The
voltage must be within the range listed on the unit
nameplate. If not, do not start the equipment until the
power company has been consulted and the voltage
condition has been corrected.
Page 14
6 - Setthethermostatforacoolingdemand,turnonpower
toindoorblowerunitandclosetheoutdoorunitdiscon-
necttostarttheunit.
7- Recheckvoltagewhiletheunitisrunning.Powermust
bewithinrangeshownonthenameplate.
ThissystemischargedwithR410Arefrigerantwhichoper-
atesat muchhigherpressuresthan R22.Therecom-
mendedcheckexpansionvalveis approvedfor usewith
R410A.Donotreplaceitwitha valvethatisdesignedtobe
usedwithR22.ThisunitisNOTapprovedforusewithcoils
thatincludemeteringorificesorcapillarytubes.
Processing Procedure
The unit is factory-charged with the amount of R410A re-
frigerant indicated on the unit rating plate. This charge is
based on a matching indoor coil and outdoor coil with a 15
foot (4.6 m) line set. For varying lengths of line set, refer to
table 2 for refrigerant charge adjustment. A blank space is
provided on the unit rating plate to list the actual field
charge.
Table 4
Liquid Line Set Oz. per 5 ft. (grams per 1.5 m) adjust
Diameter from 15 ft. (4.6 m) line set*
3/8 in, 3 ounces per 5 feet
(10 ram) (85 g per 1.5 m)
*If line length is ,mater than 15 ft. (4.6 m), add this amount.
If line length is less than 15 ft. (4.6 m), subtract this amount.
,IMPORTANT
HPXA12 COOLING CYCLE
(Showing Gauge Manifold Connections)
OUTDOOR UNIT
r DISTRIBUTOR
EXPANSION/ REVERSING VALVE
CHECK VALVE__
OUT ,COR
,I I$1"*-- BIFLOW
LOW HIGH FILTER /DRIER
PRESSURE PRESSURE ILid
_ I I MOFFLERI"%
0:(IGA_UGE_A_ I10 SERVICEpoRT
_°OAHLIQUIDI..._E:::;H II_H
c° ss°ll
NOTE-Use gauge ports on vapor line valve and fiquid valve for evacuating refrigerant lines
and indoor coil. Use vapor gauge port to measure vapor pressure during charging.
NOTE - ARROWS INDICATE
DIRECTION OF REFRIGERANT FLOW
INDOOR UNIT
EXPANSION/CHECK
VALVE
OOR
I COIL
L
Figure 15
Page 15
Theoutdoorunitshouldbechargedduringwarmweather.
However,applicationsariseinwhichchargingmustoccur
inthe coldermonths.The method of charging is deter-
mined by the unit's refrigerant metering device and the
outdoor ambient temperature.
Measure the liquid line temperature and the outdoor ambi-
ent temperature as outlined below:
1 - Connect the manifold gauge set to the service valves:
• low pressure gauge to vapor valve service port
• high pressure gauge to liquid valve service port
Close manifold gauge set valves. Connect the center
manifold hose to an upright cylinder of R410A. See fig-
ure 15.
2 - Set the room thermostat to call for heat. This will create
the necessary load for properly charging the system in
the cooling cycle.
3 - Use a digital thermometer to record the outdoor ambi-
ent temperature.
4 - When the heating demand has been satisfied, switch
the thermostat to cooling mode with a set point of 68_F
(20_%). When pressures have stabilized, use a digital
thermometer to record the liquid line temperature.
5 - The outdoor temperature will determine which charg-
ing method to use. Proceed with the appropriate charg-
ing procedure.
Weighing in the Charge TXV Systems-
Outdoor Temp < 65°F (18°C)
If the system is void of refrigerant, or if the outdoor ambient
temperature is cool, the refrigerant charge should be
weighed into the unit. Do this after any leaks have been re-
paired.
1 - Recover the refrigerant from the unit.
2- Conduct a leak check, then evacuate as previously
outlined.
3 - Weigh in the unit nameplate charge.
If weighing facilities are not available or if you are charging
the unit during warm weather, follow one of the other proce-
dures outlined below.
Subcooling Method
Outdoor Temp. < 65°F (18°C)
When the outdoor ambient temperature is below 65°F
(18°C), use the subcooling method to charge the unit. It
may be necessary to restrict the air flow through the out-
door coil to achieve pressures in the 325-375 psig
(2240-2585 kPa) range. These higher pressures are nec-
essary for checking the charge. Block equal sections of air
intake panels and move obstructions sideways until the liq-
uid pressure is in the 325-375 psig (2240-2585 kPa) range.
See figure 16.
Blocking Outdoor Coil
*Outdoor coil should be
blocked one side
at a time with cardboard
or plastic sheet until proper
testing pressures
are reached.
cardboard or *four-sided
plastic sheet unit shown
Figure 16
1 - With the manifold gauge hose still on the liquid service
port and the unit operating stably, use a digital ther-
mometer to record the liquid line temperature.
2 - At the same time, record the liquid line pressure reading.
3 - Read the liquid line pressure from the gauge and convert
it to heat pump temperature using the temperature/pres-
sure chart for R410A refrigerant provided in table 8,
4 - Subtract the liquid line temperature from the saturation
temperature (according to the chart) to determine sub-
cooling. (Saturation temperature - Liquid line tem-
perature = Subcooling)
5 - Compare the subcooling value with those in table 5, If
subcooling is greater than shown, recover some refrig-
erant. If subcooling is less than shown, add some re-
frigerant, Some R410A cylinders are equipped with
a dip tube which allows you to draw liquid refriger-
ant from the bottom of the cylinder without turning
the cylinder upside-down. The cylinder will be
marked if it is equipped with a dip tube.
Table 5
Subcooling Values for Charging
Model Number Subcooling Values
Conversion Temp. - Liquid Line Temp. °F (°C)
HPXA12-18 85 (4.7)
HPXA12-24 125 (6.9)
HPXA12-30 5.5 (3.1)
HPXA12-36 8.5 (4.7)
HPXA12-42 8.5 (4.7)
HPXA12-48 7 (3.9)
HPXA12-60 7 (3.9)
Charging Using Normal Operating Pressures
and the Approach Method
Outdoor Temp. >_65°F (18°C)
The following procedure is intended as a general guide and
is for use on expansion valve systems only. For best results,
indoor temperature should be 70°F (21°C) to 80°F (26°C).
Monitor system pressures while charging.
1 - Record outdoor ambient temperature using a digital
thermometer.
2 - Attach high pressure gauge set and operate unit for
several minutes to allow system pressures to stabilize.
Page 16
3- Comparestabilizedpressureswiththoseprovidedin
table7, "NormalOperatingPressures."Minorvaria-
tionsinthesepressuresmaybeexpectedduetodiffer-
encesin installations,Significantdifferencescould
meanthatthesystemisnotproperlychargedorthata
problemexistswithsomecomponentinthesystem.
Pressureshigherthanthoselistedindicatethatthe
systemis overcharged.Pressureslowerthanthose
listedindicatethatthesystemisundercharged.Verify
adjustedchargeusingtheapproachmethod.
ApproachMethod
4 - Usethesamedigitalthermometerusedtocheckout-
doorambienttemperaturetocheckliquidlinetempera-
ture.Verifytheunitchargeusingtheapproachmethod.
Thedifferencebetweentheambientandliquidtemper-
aturesshouldmatchvaluesgivenintable6.Addrefrig-
eranttolowertheapproachtemperatureandremoveit
toincreasetheapproachtemperature,Lossofcharge
resultsinlowcapacityandefficiency.
5- Ifthevaluesdonotagreewiththethoseintable6,add
refrigerantto lowertheapproachtemperatureor re-
coverrefrigerantfromthesystemto increasetheap-
proachtemperature.
Table 6
Approach Values for Charging
Model Number Approach Temperature
Liquid Line Temp. -Outdoor Ambient °F (°C)
HPXA12-18 5 (2.8)
HPXA12-24 8.0 (4.4)
HPXA12-30 12.5 (6.9)
HPXA12-36 13 (7.2)
HPXA12-42 13 (7.2)
HPXA12-48 8.5 (4.7)
HPXA12-60 12 (6.7)
AIMPORTANT
Table 7
Normal Operating Pressures
(Liquid +10 and Vapor +5 psig)
Cooling Operation
Outdoor Coil HPXA12-18 HPXA12-24 HPXA12-30 HPXA12-36 HPXA12-42 HPXA12-48 HPXA12-60
Entering Air Liquid Vapor Liquid vapor Liquid Vapor Liquid Vapor Liquid Vapor Liquid Vapor Liquid Vapor
Temp. °F (°C)
65 (18.3) 223 147 254 130 244 136 262 135 260 133 240 126 250 123
75 (23.9) 270 149 290 134 282 139 304 138 300 135 280 130 300 132
85 (29.4) 312 150 335 137 325 141 349 141 345 137 320 134 345 137
95 (35.0) 360 152 382 140 375 143 399 143 397 139 360 136 378 140
105 (40.6) 406 154 433 143 426 145 454 146 452 142 415 137 430 142
115 (46.1) 463 155 490 146 485 147 514 149 510 145 470 139 497 145
Heating Operation
Outdoor Coil HPXA12-18 HPXA12-24 HPXA12-30 HPXA12-36 HPXA12-42 HPXA12-48 HPXA12-60
Entering Air
Temp. °F (°C) Liquid Vapor Liquid Vapor Liquid Vapor Liquid Vapor Liquid Vapor Liquid Vapor Liquid Vapor
20 (-6.6) 265 63 295 59 340 60 278 59 288 60 315 60 282 57
30 (-1.1) 280 78 315 72 350 75 290 72 297 70 325 74 300 70
40 (4.4) 294 96 335 87 362 90 305 89 310 85 340 90 310 82
50 (10.0) 310 112 350 103 374 110 317 105 325 105 360 106 325 92
60 (15.5) 320 133 375 120 390 132 333 128 344 127 380 128 335 100
Page 17
Temp.°F
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
6O
61
62
Pressure Psig
100.8
102.9
105.0
107.1
109.2
111.4
113.6
115.8
118.0
120.3
122.6
125.0
127.3
129.7
132.2
134.6
137.1
139.6
142.2
144.8
147.4
150.1
152.8
155.5
158.2
161.0
163.9
166.7
169.6
172.6
195.5
Table 8
R410A Temperature/Pressure Chart
Temp.°F Pressure Psig Temp. °F Pressure Psig Temp.
178.5
181.6
184.3
187.7
190.9
194.1
197.3
200.6
203.9
207.2
210.6
214.0
217.4
220.9
224.4
228.0
231.6
235.3
239.0
242.7
246.5
250.3
254.1
258.0
262.0
266.0
270.0
274.1
278.2
282.3
286.5
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
290.8 125
295.1 126
299.4 127
303.8 128
308.2 129
312.7 130
317.2 131
321.8 132
326.4 133
331.0 134
335.7 135
340.5 136
345.3 137
350.1 138
355.0 139
360.0 140
365.0 141
370.0 142
375.1 143
380.2 144
385.4 145
390.7 146
396.0 147
401.3 148
406.7 149
412.2 150
417.7 151
423.2 152
428.8 153
434.5 154
440.2 155
°F Pressure Psig
445.9
451.8
457.6
463.5
469.5
475.6
481.6
487.8
494.0
500.2
506.5
512.9
519.3
525.8
532.4
539.0
545.6
552.3
559.1
565.9
572.8
579.8
586.8
593.8
601.0
608.1
615.4
622.7
630.1
637.5
645.0
63
64
65
66
67
68
69
7O
71
72
73
74
75
76
77
78
79
8O
81
82
83
84
85
86
87
88
89
9O
91
92
93
is isolated from power and field-provided relays bypass the
outdoor thermostats, An amber indicating light simultaneously
The outdoor unit and indoor blower cycle on demand from
the room thermostat. When the thermostat blower switch is
in the ON position, the indoor blower operates continuously.
Service Light Operation
The thermostat is not included with the unit and must be
purchased separately, Some outdoor thermostats incorpo-
rate isolating contacts and an emergency heat function
(which includes an amber indicating light). The service light
thermostat will enable the emergency heat light function on
the room thermostat,
Emergency Heat (Amber Light)
An emergency heat function is designed into some room ther-
mostats. This feature is applicable when isolation of the out-
door unit is required, or when auxiliary electric heat is staged
by outdoor thermostats, When the room thermostat is placed
in the emergency heat position, the outdoor unit control circuit
comes on to remind the homeowner that he is operating in the
emergency heat mode,
Emergency heat is usually used during an outdoor unit
shutdown, but it should also be used following a power out-
age if power has been off for over an hour and the outdoor
temperature is below 50°F (10°C). System should be left in
the emergency heat mode at least six hours to allow the
crankcase heater sufficient time to prevent compressor
slugging,
Filter Brier
The unit is equipped with a large-capacity biflow filter drier
which keeps the system clean and dry, If replacement is
necessary, order another of the same design and capacity,
The replacement filter drier must be suitable for use with
R410A refrigerant,
Page 18
LowPressureSwitch
TheHPXA12isequippedwithanauto-resetlowpressure
switchwhichislocatedonthevaporline.Theswitchshuts
offthecompressorwhenthevaporpressurefallsbelowthe
factorysetting.Thisswitchisignoredduringdefrostopera-
tionandwhentheoutdoortemperaturegoesbelow15°F.
Theswitchcloseswhenitisexposedto60psigandopens
at25psig,Itisnotadjustable,
HighPressureSwitch
TheHPXA12isequippedwithanauto-resethighpressure
switch(single-pole,single-throw)whichislocatedonthe
liquidline,Theswitchshutsoffthecompressorwhendis-
chargepressurerisesabovethefactorysetting.Theswitch
is normallyclosedand is permanentlyadjustedto trip
(open)at640+ 10psig(4412+69kPa).
NOTE -A Schrader core is under the pressure switches.
HPXA12 Defrost Control Board
Note -Component Locations Will Vary With Board Manufacturer
Figure 17
Page 19
Demand Defrost System
The demand defrost controller uses basic differential tem-
perature means to detect when the system performs poor-
ly because of ice build-up on the outdoor coil. The control-
ler also uses "self-calibrating" principles to calibrate itself
when the system starts and after every time the system
defrosts. The control board has the following compo-
nents: defrost relays, anti-short cycle timed-off control,
pressure switch/safety control, 5-trip lockout circuit,
manufacturing test mode, ambient and coil temperature
sensors, field selectable termination temperature pins, and
a field low voltage connection terminal strip. See figure 17.
The control monitors ambient temperature, outdoor coil
temperature and total run time to determine when a de-
frost cycle is required. Two temperature probes are per-
manently attached to the control. The coil temperature
probe is designed with a spring clip to allow mounting to
the outside coil tubing. The location of the coil sensor is
important for proper defrost operation.
NOTE -The logic of the demand defrost board accurately
measures the performance of the system as frost accumu-
lates on the outdoor coil. This typically will translate into
longer running time between defrost cycles as more frost
accumulates on the outdoor coil before the board initiates
defrost cycles.
The temperature probes cannot be removed from the con-
trol. The control and the attached probes MUST be re-
placed as a unit. Do not attempt to cut or splice probe wires.
Diagnostic LEDs
The defrost board uses two LEDs for diagnostics. The
LEDs flash a specific sequence according to the diagnos-
tic condition, See table 9,
HI-PS/LO-PS Terminals
The unit's automatic reset pressure switches are wired to
the PS terminals. The high-pressure switch is factory
wired to the HI-PS terminal, and the low-pressure switch
is factory-wired to LO-PS terminal.
The path between Y1 (input) and Y1 Out is interlocked
through the pressure switches. When one of the pressure
switches trip, the board will cycle off the compressor and
the 5-strike counter in the board will count one strike.
5-Strike Lockout Feature
• The internal control logic of the board counts the pres-
sure switch trips only while the Y1 (Input) line is active, If
a pressure switch opens and closes twice during a Y1
(Input), the control logic will reset the pressure switch
trip counter to zero at the end of the Y1 (Input), If the
pressure switch opens for a fifth time during the current
Y1 (Input), the control will enter a lockout condition,
• The 5-strike pressure switch lockout condition can be
reset by cycling OFF the 24-volt power to the control
board or by shorting the TEST pins, All timer functions
(run times) will also be reset,
• If a pressure switch opens while the Y1 Out line is en-
gaged, a 5-minute short cycle will occur after the switch
closes,
Delay Mode
The defrost board has a field-selectable function to reduce
occasional sounds that may occur while the unit is cycling
in and out of the defrost mode. When a jumper is installed
on the DELAY pins, the compressor will be cycled off for 30
seconds going in and out of the defrost mode, Units are
shipped with jumper installed on DELAY pins.
NOTE -The 30 second off cycle is not functional when jum-
pering the TEST pins.
Operational Description
The defrost control board has three basic operational
modes: normal, defrost, and calibration,
Normal Mode
The demand defrost board monitors the O line, to deter-
mine the system operating mode (heat/cool), outdoor am-
bient temperature, coil temperature (outdoor coil) and
compressor run time to determine when a defrost cycle is
required,
Defrost Mode
Refer to table 9 for demand defrost operation,
Calibration Mode
The board is considered uncalibrated when power is ap-
plied to the board, after cool mode operation, or if the coil
temperature exceeds the termination temperature when it
is in heat mode. Calibration of the board occurs after a de-
frost cycle to ensure that there is no ice on the coil. During
calibration, the temperature of both the coil and the ambi-
ent sensor are measured to establish the temperature dif-
ferential which is required to allow a defrost cycle,
Page 20
Table 9
Defrost Control Board Diagnostic Led
LED 1 LED 2 Condition Possible Cause(s) Solution
1 No power (24V) to board terminals 1 Check control transformer power
OFF OFF Power problem R & C. (24V).
2 Board failure. 2 If power is available and LED(s) are
unlit, replace board and all sensors.
1 Sensor function will resume when
I Coil temperature outside of sensor coil temperature is between -20°F
range, and 110°F.
ON ON Coil sensor problem 2 Faulty sensor wiring connections at 2 Check sensor wiring connections at
board or poor sensor contact on coil. board and sensor contact on coil.
3 Sensor failure. 3 Replace board and all sensors.
1 Sensor function will resume when
1 Ambient temperature outside of coil temperature is between -20°F
sensor range, and 110°F.
OFF ON Ambient sensor problem 2 Faulty sensor wiring connections at 2Check sensor wiring connections at
board or sensor, board and sensor.
3 Sensor failure. 3 Replace board and all sensors.
Unit operating normally or in standby None required.
Normal operation mode.
1 Restricted air flow over indoor or
outdoor coil.
FLASH
ON
ON
FLASH
ALTERNATING
FLASH
FLASH
OFF
FLASH
ON
ALTERNATING
FLASH
5-Strike pressure lockout
(Short test pins or reset
24V power to board to
override lockout)
Low pressure switch circuit
open during Y1 demand
High pressure switch cir-
cuit open during Y1 de-
mand
2Improper refrigerant charge.
3 Improper metering device opera-
tion.
4 Poor contact between coil sensor
and coil.
1 Remove any blockages or restric-
tions. Check outdoor fan motor for
proper operation.
2 Check approach, superheat & sub-
cooling temperatures.
3 Check system pressures. Repair
leaks. Replace metering device.
4 Make sure that sensor is properly
positioned on coil and that firm con-
tact is established. Refer to service
manual for proper placement.
5-minute delay Thermostat demand for cooling or
(Jumper test pins to over- outdoor operation. Unit operating in None required.
ride delay) 5-minute anti-short-cycle mode.
Demand Defrost Operation
The demand defrost control board initiates a defrost cycle based on either frost detection or time.
Frost Detection - If the compressor runs longer than 34 minutes and the actual difference between the clear coil and frosted coil temperatures exceeds
the maximum difference allowed by the control, a defrost cycle will be initiated.
IMPORTANT- The demand defrost control board will allow a greater accumulation of frost and will initiate fewer defrost cycles than a time/temperature
defrost system.
Time - If 6 hours of heating mode compressor run time has elapsed since the last defrost cycle while the coil temperature remains below 35°F (2°C),
the demand defrost control will initiate a defrost cycle.
Actuation - When the reversing valve is de-energized, the Y1 circuit is energized, and the coil temperature is below 35°F (2°C), the board logs the
compressor run time. Ifthe board is not calibrated, a defrost cycle will be initiated after 34 minutes of heating mode compressor run time. The control
will attempt to self-calibrate after this (and all other) defrost cycle(s). Calibration success depends on stable system temperatures during the 2g-minute
calibration period. If the board fails to calibrate, another defrost cycle will be initiated after 90 minutes of heating mode compressor run time. Once the
defrost board is calibrated, it will use demand defrost logic to initiate a defrost cycle. A demand defrost system initiates defrost when the difference be-
tween the clear coil and frosted coil temperatures exceeds the maximum difference allowed by the control OR after 6 hours of heating mode compressor
run time has been logged since the last defrost cycle.
Termination - The defrost cycle ends when the coil temperature exceeds the termination temperature or after 14 minutes of defrost operation. If the
defrost is terminated by the 14-minute timer, another defrost cycle will be initiated after 34 minutes of run time.
Test Mode - When Y1 is energized and 24V power is being applied to the board, a test cycle can be initiated by placing the termination temperature
lumper across the 'Test" pins for 2 to 5 seconds. If the jumper remains across the 'Test" pins longer than 5 seconds, the control will ignore the test pins
and revert to normal operation. The jumper will initiate one cycle per test.
Page 21
kWARNING
Maintenance and service must be performed by a qualified
installer or service agency. At the beginning of each cooling
season, the system should be checked as follows:
Outdoor Unit
1 - Clean and inspect outdoor coil (may be flushed with a
water hose). Ensure power is off before cleaning.
2 - Outdoor unit fan motor is pre-lubricated and sealed, No
further lubrication is needed.
3 - Visually inspect all connecting lines, joints and coils for
evidence of oil leaks.
4 - Check all wiring for loose connections,
5 - Check for correct voltage at unit (unit operating),
6 - Check amp draw on outdoor fan motor.
Unit nameplate Actual
7 - Inspect drain holes in coil compartment base and clean
if necessary,
NOTE -If insufficient heating or cooling occurs, the unit
should be gauged and refrigerant charge should be
checked,
Indoor Coil
1 - Clean coil if necessary,
2 - Check connecting lines, joints and coil for evidence of
oil leaks,
3 - Check condensate line and clean if necessary,
Indoor Unit
1 - Clean or change filters,
2 - Lennox blower motors are prelubricated and permanent-
ly sealed, No more lubrication is needed.
3 - Adjust blower speed for cooling, Measure the pressure
drop over the coil to determine the correct blower CFM.
Refer to the unit information service manual for pressure
drop tables and procedure,
4 - Belt Drive Blowers - Check belt for wear and proper
tension,
5 - Check all wiring for loose connections,
6- Check for correct voltage at unit, (blower operating)
7 - Check amp draw on blower motor.
Motor nameplate Actual
Refer to the Engineering Handbook for optional accesso-
ries that may apply to this unit, The following may or may
not apply:
• Loss of Charge Kit
• High Pressure Switch Kit
• Compressor Monitor
• Compressor Crankcase Heater
• Hail Guards
• Mounting Bases
• Stand-off Kit
• Sound Cover
• LowAmbient Kit
• Monitor Kit
• Mild Weather Kit
In order to ensure peak performance, your system must be
properly maintained. Clogged filters and blocked airflow
prevent your unit from operating at its most efficient level,
Ask your Lennox dealer to show you where your indoor
unit's filter is located. It will be either at the indoor unit
(installed internal or external to the cabinet) or behind a re-
turn air grille in the wall or ceiling. Check the filter monthly
and clean or replace it as needed,
Disposable filters should be replaced with a filter of the
same type and size. If you are unsure about the filter you
need for your system, call your Lennox dealer for assis-
tance.
IMPORTANT
Many indoor units are equipped with reusable foam fil-
ters, These filters can be cleaned with a mild soap and
water solution. Rinse the filter thoroughly and let it dry
completely before it is returned to the unit or grille,
The filter and all access panels must be in place any
time the unit is in operation.
Your system may be equipped with an electronic air clean-
er which will provide respiratory relief by removing up to 90
percent of all airborne particles which pass through it. If it
is, ask your dealer to instruct you on its maintenance.
Your indoor coil is equipped with a drain pan to collect con-
densate formed as your system removes humidity from the
inside air. Have your dealer show you where the main con-
densate drain (and auxiliary drain, if applicable) runs and
how to check the drain for any obstruction.
It is also very important to provide unrestricted airflow to the
outdoor unit. Leaves, trash or shrubs crowding the unit
cause the outdoor unit to work harder and use more ener-
gy. Keep shrubbery trimmed away from the unit and period-
Page 22
icallycheckfordebriswhichmayhavecollectedaroundthe
unit,
Heat Pump Operation
Your new Lennox heat pump has several characteristics
that you should be aware of:
Your heat pump satisfies heating demand by delivering
large amounts of warm air into the living space. This is quite
different from gas- or oil-fired furnaces or an electric fur-
nace which deliver lower volumes of considerably hotter air
to heat the space,
Do not be alarmed if you notice frost on the outdoor coil in
the winter months, Frost develops on the outdoor coil dur-
ing the heating cycle when temperatures are below 45°F
(7°C). An electronic control activates a defrost cycle lasting
5 to 15 minutes at preset intervals to clear the outdoor coil
of the frost. During the defrost cycle, you may notice steam
rising from the outdoor unit, This is a normal occurrence.
The thermostat may engage auxiliary heat during the de-
frost cycle to satisfy a heating demand; however, the unit
will return to normal operation at the conclusion of the de-
frost cycle.
Your Lennox HPXA12 heat pump is equipped with a com-
pressor crankcase heater which protects the compressor
from refrigerant slugging during cold weather operation. If
power to your unit has been interrupted for several hours
or more, set the room thermostat selector to the "Emergen-
cy Heat" setting to obtain temporary heat without the risk
of serious equipment damage, In this operating mode, all
heating demand will be satisfied by auxiliary heat, Com-
pressor operation is locked out during Emergency Heat op-
eration. After a six-hour compressor crankcase heater
warm-up period, the thermostat can be switched to the
"Heat" setting and normal operation will resume,
Thermostat Operation
Though your thermostat may vary somewhat from the de-
scription below, its operation will be similar.
Temperature Setting Levers
Most heat pump thermostats have two temperature selec-
tor levers: one for heating and one for cooling. Set the lev-
ers or dials to the desired temperature setpoints for both
heating and cooling. Avoid frequent temperature adjust-
ment; turning the unit off and back on before pressures
equalize puts stress on the unit compressor.
Fan Switch
In AUTO or INT (intermittent) mode, the blower operates
only when the thermostat calls for heating or cooling. This
mode is generally preferred when humidity control is a
priority. The ON or CONT mode provides continuous in-
door blower operation, regardless of whether the compres-
sor or auxiliary heat are operating. This mode is required
when constant air circulation or filtering is desired.
System Switch
Set the system switch for heating, cooling or auto opera-
tion. The auto mode allows the heat pump to automatically
switch from heating mode to cooling mode to maintain pre-
determined comfort settings. Many heat pump thermostats
are also equipped with an emergency heat mode which
locks out heat pump operation and provides temporary
heat supplied by the auxiliary heat.
Indicating Light
Most heat pump thermostats have an amber light which in-
dicates when the heat pump is operating in the emergency
heat mode.
Temperature Indicator
The temperature indicator displays the actual room tem-
perature.
Programmable Thermostats
Your Lennox system may be controlled by a programmable
thermostat. These thermostats provide the added feature
of programmable time-of-day setpoints for both heating
and cooling. Refer to the user's information manual pro-
vided with your particular thermostat for operation details.
Preservice Check
If your system fails to operate, check the following before
calling for service:
• Check to see that all electrical disconnect switches are
ON,
• Make sure the room thermostat temperature selector is
properly set.
• Make sure the room thermostat system switch is proper-
ly set.
• Replace any blown fuses, or reset circuit breakers.
• Make sure unit access panels are in place.
• Make sure air filter is clean.
• Locate and record unit model number before calling.
Page 23
JobName Start-Up and Performance Check List
Job No. Date
Job Location City
Installer City
Unit Model No. Serial No.
State
State
Service Technician
Nameplate Voltage
Rated Load Ampacity
Maximum Fuse or Circuit Breaker
Electrical Connections Tight? []
Indoor Blower RPM
Cooling (2nd stage)
Liquid Line Pressure Vapor Pressure
Heating (2nd stage)
Liquid Line Pressure Vapor Pressure
Refrigerant Lines: Leak Checked? [] Properly Insulated? []
Service Valves Fully Opened? [] Service Valve Caps Tight? []
Sequence of Operation
Heating Correct [] Cooling Correct []
Amps: 1st stage
Indoor Filter Clean? []
S,R Drop Over Indoor (Dry)
2nd Stage
Supply Voltage (Unit Off) --
-- Outdoor Coil Entering Air Temp.
Refrigerant Charge Checked? []
Refrigerant Charge Checked? []
Outdoor Fan Checked? []
Voltage With Compressor Operating --
Thermostat
Calibrated? [] Properly Set? [] Level? []
Page 24
