TRANE 4TWR6 Heat Pumps Instruction Manual

TRANE 4TWR6 Heat Pumps

Product Information

The product is a heat pump with the model number 4TWR6. It contains R-410A refrigerant and approved POE compressor oil. The unit’s dimensions and weight vary based on the model, as listed in Table 2.1.

Product Usage Instructions

Before installing or servicing the heat pump, it is important to note that all phases of the installation must comply with national, state, and local codes. Additionally, extreme caution should be exercised when handling the unit to prevent personal injury or property damage.

When using existing refrigerant lines, ensure that all joints are brazed rather than soldered. When opening the liquid line service valve, turn it counterclockwise until the valve stem just touches the rolled edge to avoid an abrupt release of system charge that could cause personal injury or property damage. Before servicing the unit, disconnect power and discharge capacitors to avoid hazardous voltage. During installation, testing, servicing, and troubleshooting of the product, it may be necessary to work with live electrical components. Follow all electrical safety precautions to prevent death or serious injury. When mounting the outdoor unit on a roof, ensure that the roof can support the unit’s weight. Properly selected isolation is recommended to alleviate sound or vibration transmission to the building structure.

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Installation and Operation of Manual Heat Pumps

4TWR6
ALL phases of this installation must comply with NATIONAL, STATE AND LOCAL CODES
IMPORTANT ­ This Document is customer property and is to remain with this unit. Please return to the service information pack upon completion of work. These instructions do not cover all variations in systems or provide for every possible contingency to be met in connection with the installation. Should further information be desired or should particular problems arise which are not covered sufficiently for the purchaser’s purposes, the matter should be referred to your installing dealer or local distributor. Note: The manufacturer recommends installing only approved matched indoor and outdoor systems. All of the manufacturer’s split systems are A.H.R.I. rated only with TXV/EEV indoor systems. Some of the benefits of installing approved matched indoor and outdoor split systems are maximum efficiency, optimum performance and the best overall system reliability.

Section 1. Safety

! WARNING
This information is intended for use by individuals possessing adequate backgrounds of electrical and mechanical experience. Any attempt to repair a central air conditioning product may result in personal injury and/or property damage. The manufacture or seller cannot be responsible for the interpretation of this information, nor can it assume any liability in connection with its use.

! WARNING
These units use R-410A refrigerant which operates at 50 to 70% higher pressures than R-22. Use only R-410A approved service equipment. Refrigerant cylinders are painted a “Rose” color to indicate the type of refrigerant and may contain a “dip” tube to allow for charging of liquid refrigerant into the system. All R-410A systems use a POE oil that readily absorbs moisture from the atmosphere. To limit this “hygroscopic” action, the system should remain sealed whenever possible. If a system has been open to the atmosphere for more than 4 hours, the compressor oil must be replaced. Never break a vacuum with air and always change the driers when opening the system for component replacement. For specific handling concerns with R-410A and POE oil reference Retrofit Bulletins SS-APG006-EN and APP-APG011-EN.

! WARNING
UNIT CONTAINS R-410A REFRIGERANT! R-410A operating pressures exceed the limit of R-22. Proper service equipment is required. Failure to use proper service tools may result in equipment damage or personal injury. SERVICE USE ONLY R-410A REFRIGERANT AND APPROVED POE COMPRESSOR OIL.

! WARNING
Extreme caution should be exercised when opening the Liquid Line Service Valve. Turn counterclockwise until the valve stem just touches the rolled edge. No torque is required. Failure to follow this warning will result in abrupt release of system charge and may result in personal injury and /or property damage.

! WARNING
HAZARDOUS VOLTAGE! Disconnect power and discharge capacitors before servicing.

! WARNING
LIVE ELECTRICAL COMPONENTS! During installation, testing, servicing, and troubleshooting of this product, it may be necessary to work with live electrical components. Failure to follow all electrical safety precautions when exposed to live electrical components could result in death or serious injury.

! CAUTION
If using existing refrigerant lines make certain that all joints are brazed, not soldered.

! CAUTION
Scroll compressor dome temperatures may be hot. Do not touch the top of compressor; it may cause minor to severe burning.

! CAUTION
HOT SURFACE! May cause minor to severe burning. Failure to follow this Caution could result in property damage or personal injury. Do not touch top of compressor.

! CAUTION

CONTAINS REFRIGERANT! Failure to follow proper procedures can result in personal illness or injury or severe equipment damage. System contains oil and refrigerant under high pressure. Recover refrigerant to relieve pressure before opening system.

! CAUTION
GROUNDING REQUIRED! Failure to inspect or use proper service tools may result in equipment damage or personal injury. Reconnect all grounding devices. All parts of this product that are capable of conducting electrical current are grounded. If grounding wires, screws, straps, clips, nuts, or washers used to complete a path to ground are removed for service, they must be returned to their original position and properly fastened.

2

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Section 2. Unit Location Considerations
2.1 Unit Dimensions and Weight

Table 2.1

Unit Dimensions and Weight

Models

H x D x W (in) Weight* (lb)

4TWR6024N 41 x 34 x 37

236

4TWR6036N 45 x 34 x 37

257

4TWR6048N 45 x 34 x 37

292

4TWR6060N 45 x 34 x 37

293

• Weight values are estimated.

W H
D

When mounting the outdoor unit on a roof, be sure the roof will support the unit’s weight. Properly selected isolation is recommended to alleviate sound or vibration transmission to the building structure.

Refrigerant Piping Limits

1. The maximum length of refrigerant lines from outdoor to indoor unit should NOT exceed 150 feet. 2. The maximum vertical change should not exceed fifty (50) feet. 3. Service valve connection diameters are shown in Table 5.1. Note: For line lengths greater than fifty (50) feet, Refer to Refrigerant Piping Application Guide,
SS-APG006F-EN, or Refrigerant Piping Software Program.

Standard Line Set 150″ Max Line Length

50” Max Vertical Change

2.3 Suggested Locations for Best Reliability
Ensure the top discharge area is unrestricted for at least five (5) feet above the unit. Three (3) feet clearance must be provided in front of the control box (access panels) and any other side requiring service. Do not locate close to bedrooms as operational sounds may be objectionable. Avoid locations such as near windows where condensation and freezing defrost vapor can annoy a customer. Position the outdoor unit a minimum of 12″ from any wall or surrounding shrubbery to ensure adequate airflow. Outdoor unit location must be far enough away from any structure to prevent excess roof runoff water or icicles from falling directly on the unit.
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Avoid Install Near Bedrooms
Min. 12″ to Shrubbery

50” Max Vertical Change
Min 5′ Unrestricted Min 3′ Unrestricted Access Panel
3

Cold Climate Considerations
NOTE: It is recommended that these precautions be taken for units being installed in areas where snow accumulation and prolonged below freezing temperatures occur.
· Units should be elevated 3-12 inches above the pad or rooftop, depending on local weather. This additional
height will allow drainage of snow and ice melted during defrost cycle prior to its refreezing. Ensure that drain holes in unit base pan are not obstructed preventing draining of defrost water.
· If possible, avoid locations that are likely to accumulate snow drifts. If not possible, a snow drift barrier should be
installed around the unit to prevent a build-up of snow on the sides of the unit.

Coastal Considerations
If installed within one mile of salt water, including seacoasts and inland waterways, models without factory supplied Seacoast Salt Shields require the addition of BAYSEAC001 (Seacoast Kit) at installation time.

Section 3. Unit Preparation
3.1 Prepare The Unit For Installation
STEP 1 – Check for damage and report promptly to the carrier any damage found to the unit. STEP 2 – To remove the unit from the pallet, remove tabs by cutting with a sharp tool.
Section 4. Setting the Unit
4.1 Pad Installation When installing the unit on a support pad, such as a concrete slab, consider the following:
· The pad should be at least 1″ larger than the unit on all sides. · The pad must be separate from any structure. · The pad must be level. · The pad should be high enough above grade to allow for drainage. · The pad location must comply with National, State, and Local codes.

Section 5. Refrigerant Line Considerations
5.1 Refrigerant Line and Service Valve Connection Sizes

Model
4TWR6024N 4TWR6036N 4TWR6048N 4TWR6060N

Table 5.1

Line Sizes

Service Valve Connection Sizes

Vapor Line

Liquid Line

Vapor Line Connection

Liquid Line Connection

5/8

3/8

3/4

3/8

3/4

3/8

3/4

3/8

7/8

3/8

7/8

3/8

1-1/8

3/8

7/8

3/8

Alternate Line Sizes Model
4TWR6024N 4TWR6036N 4TWR6048N 4TWR6060N

Line Sizes

Vapor Line

Liquid Line

3/4

3/8

5/8

3/8

7/8

3/8

3/4

3/8

3/4

3/8

7/8

3/8

Service Valve Connection Sizes

Vapor Line Connection

Liquid Line Connection

3/4

3/8

3/4

3/8

3/4

3/8

7/8

3/8

7/8

3/8

7/8

3/8

4

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5.2 Factory Charge
The outdoor condensing units are factory charged with the system charge required for the outdoor condensing unit, ten (10) feet of tested connecting line, and the smallest rated indoor evaporative coil match. Always verify proper system charge via subcooling (TXV/EEV) or superheat (fixed orifice) per the unit nameplate.
5.3 Required Refrigerant Line Length
Determine required line length and lift. You will need this later in STEP 2 of Section 14.

Total Line Length = __ Ft. Total Vertical Change (lift) = __ Ft.

Line Length

5.4 Refrigerant Line Insulation
Important: The Vapor Line must always be insulated. DO NOT allow the Liquid Line and Vapor Line to come in direct (metal to metal) contact.

Liquid Line

Vapor Line Insulation

5.5 Reuse Existing Refrigerant Lines
! CAUTION
If using existing refrigerant lines make certain that all joints are brazed, not soldered.

For retrofit applications, where the existing indoor evaporator coil and/or refrigerant lines will be used, the following precautions should be taken:
· Ensure that the indoor evaporator coil and refrigerant lines are the correct size. · Ensure that the refrigerant lines are free of leaks, acid, and oil.

Section 6. Refrigerant Line Routing

6.1 Precautions

Important: Take precautions to prevent noise within the building structure due to vibration transmission from the refrigerant lines.

Comply with National, State, and Local Codes when isolating line sets from joists, rafters, walls, or other structural elements.

For Example: · When the refrigerant lines have to be fastened to floor joists or other framing in a structure, use isolation type
hangers. · Isolation hangers should also be used when refrigerant lines are run in stud spaces or enclosed ceilings. · Where the refrigerant lines run through a wall or sill, they should be insulated and isolated. · Isolate the lines from all ductwork. · Minimize the number of 90º turns.

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5

8 Feet Maximum

Joist/Rafter Isolator

Side View

8 Feet Maximum
Secure Vapor line from joists using isolators every 8 ft. Secure Liquid Line directly to Vapor line using tape, wire, or other appropriate method every 8 ft.

Isolation From Joist/Rafter

Line Set

8 Feet Maximum

Side View

8 Feet Maximum Secure Vapor Line using isolators every 8 ft. Secure Liquid Line directly to Vapor Line using tape, wire, or other appropriate method every 8 ft.
Isolation In Wall Spaces

Wall Isolator
Line Set

Wall

Sealant
Insulation Vapor Line

Isolation Through Wall 6

Ductwork
Isolator Line Set DO NOT hang line sets from ductwork 18-AC104D1-1G-EN

Section 7. Refrigerant Line Brazing
7.1 Braze The Refrigerant Lines
STEP 1 – Remove caps or plugs. Use a deburing tool to debur the pipe ends. Clean both internal and external surfaces of the tubing using an emery cloth.
STEP 2 – Remove the pressure tap cap and valve cores from both service valves.
STEP 3 – Purge the refrigerant lines and indoor coil with dry nitrogen.
STEP 4 – Wrap a wet rag around the valve body to avoid heat damage and continue the dry nitrogen purge. Braze the refrigerant lines to the service valves. For units shipped with a field-installed external drier, check liquid line filter drier’s directional flow arrow to confirm correct direction of refrigeration flow (away from outdoor unit and toward evaporator coil) as illustrated. Braze the filter drier to the Liquid Line. Continue the dry nitrogen purge. Do not remove the wet rag until all brazing is completed. Important: Remove the wet rag before stopping the dry nitrogen purge. Note: Install drier in Liquid Line. NOTE: Precautions should be taken to avoid heat damage to basepan during brazing. It is recommended to keep the flame directly off of the basepan.
STEP 5 – Replace the pressure tap valve cores after the service valves have cooled.

STEP 1

STEP 2

STEP 3

3-4″ from valve

STEP 4

STEP 5

Section 8. Refrigerant Line Leak Check
Check For Leaks
STEP 1 – Pressurize the refrigerant lines and evaporator coil to 150 PSIG using dry nitrogen. STEP 2 – Check for leaks by using a soapy solution or bubbles at each brazed location. Remove nitrogren pressure and repair any leaks before continuing.

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7

Section 9. Evacuation
9.1 Evacuate the Refrigerant Lines and Indoor Coil
Important: Do not open the service valves until the refrigerant lines and indoor coil leak check and evacuation are complete.
STEP 1 – Evacuate until the micron gauge reads no higher than 350 microns, then close off the valve to the vacuum pump.
STEP 2 – Observe the micron gauge. Evacuation is complete if the micron gauge does not rise above 500 microns in one (1) minute. Once evacuation is complete blank off the vacuum pump and micron gauge, and close the valves on the manifold gauge set.

Section 10. Service Valves
10.1 Open the Gas Service Valve
Important: Leak check and evacuation must be completed before opening the service valves. NOTE: Do not vent refrigerant gases into the atmosphere. STEP 1 – Remove valve stem cap. STEP 2 – Using an adjustable wrench, turn valve stem 1/4 turn counterclockwise to the fully open position. STEP 3 – Replace the valve stem cap to prevent leaks. Tighten finger tight plus an additional 1/6 turn.
10.2 Open the Liquid Service Valve

! WARNING
Extreme caution should be exercised when opening the Liquid Line Service Valve. Turn counterclockwise until the valve stem just touches the rolled edge. No torque is required. Failure to follow this warning will result in abrupt release of system charge and may result in personal injury and /or property damage.
Important: Leak check and evacuation must be completed before opening the service valves. STEP 1 – Remove service valve cap. STEP 2 – Fully insert 3/16″ hex wrench into the stem and back out counterclockwise until valve stem just touches the rolled edge (approximately five (5) turns.) STEP 3 – Replace the valve cap to prevent leaks. Tighten finger tight plus an additional 1/6 turn.

CAP
UNIT SIDE OF VALVE 1/4 TURN ONLY COUNTERCLOCKWISE FOR FULL OPEN POSITION
VALVE STEM

Cap
Unit Side of Service
Valve

3/16″ Hex Wrench
Rolled Edge to Captivate Stem
Hex Headed Valve System

PRESSURE TAP PORT GAS LINE CONNECTION
Gas Service Valve 8

Service Port
Liquid Service Valve 18-AC104D1-1G-EN

Section 11. Electrical – Low Voltage
11.1 Low Voltage Maximum Wire Length
Table 11.1 defines the maximum total length of low voltage wiring from the outdoor unit, to the indoor unit, and to the thermostat.

Table 11.1

24 VOLTS

WIRE SIZE

MAX. WIRE LENGTH

18 AWG

150 Ft.

16 AWG

225 Ft.

14 AWG

300 Ft.

11.2 Low Voltage Hook-up Diagrams

With TEM 6/8

Thermostat

Air Handler

Outdoor Unit

R 24 VAC HOT

R

R

With TAM 7/9

Thermostat

Air Handler

Outdoor Unit

R 24 VAC HOT

R

R

FAN

G

G

FAN

G

G

24 VAC Common

B/C

B
Blue

B

24 VAC Common

B/C

B
Blue

B

SOV

O

O

O

SOV

O

O

O

Y1 COOL/HEAT
1st STAGE

Y1

Y1

Y COOL/HEAT

1st STAGE

l

Yl

Y2 COOL/HEAT
2nd STAGE

HEATING 2nd STAGE

W

Y2

Y2

W1
White

YO

YO

Y2 COOL/HEAT
2nd STAGE

Y2

Y2

X2 EMERGENCY
HEAT
BK
WH/BLK

W2
Pink
BK
WH/BLK

X2
Black

HEATING 2nd STAGE

W

X2 EMERGENCY
HEAT

W1
White
W2
Pink

X2
Black

BK
WH/BLK

BK
WH/BLK

· Units with pigtails require wirenuts for connections. · In systems with multiple stages of electric heat, jumper W1 and W2 together if comfort control has only one stage of heat. ** TEM6 only – When using a BK enabled comfort control, cut BK jumper and bypass Y1 and Y2 at the air handler. Connect BK from comfort control to BK of the air handler · TAM7 only – When using a BK enabled comfort control, cut BK jumper on the AFC and connect BK from comfort control to BK of the air handler. TAM7 DIP switches must be configured for “HP: 2-Stage/1 Compressor”.

Note: Refer to Indoor Unit Literature for proper configuration.

Defrost Control

Defrost controls have a selectable termination temperature. As shipped, defrost will terminate at 47°F. For a higher termination temperature, cut Jumper J2 to achieve 70°F. Refer to the Defrost Control section in this document for more information.

Defrost Board Detail

Pin Identification on J5 (See Illustration) 1. TEST_COMMON (Shorting to FRC_DFT causes the control to initiate Forced Defrost. Leaving this pin open results in the normal mode of operation.) 2. FRCDFT = Forced Defrost (Short TEST COMMON to this pin for two (2) seconds to initiate a forced defrost. Remove the short after defrost initiates.)

Defrost Control Checkout

Normal operation requires:

· Status LED on board flashing 1 time/second

in standby or 2 times/second with a call for

heating or cooling.
· 24V AC between R & B

Jumper J2

J5 Test Pins

· 24V AC between Y, Y0 & B with unit operating

· Defrost initiation when FRC_DFT pin is shorted to TEST_COMMON pin.

If a defrost control problem is suspected, refer to the service information in control box.

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Section 12. Electrical – High Voltage
12.1 High Voltage Power Supply
! WARNING
LIVE ELECTRICAL COMPONENTS! During installation, testing, servicing, and troubleshooting of this product, it may be necessary to work with live electrical components. Failure to follow all electrical safety precautions when exposed to live electrical components could result in death or serious injury.
The high voltage power supply must agree with the equipment nameplate.
Power wiring must comply with national, state, and local codes.
Follow instructions on unit wiring diagram located on the inside of the control box cover and in this document included with the unit.

12.2 High Voltage Disconnect Switch Install a separate disconnect switch at the outdoor unit. For high voltage connections, flexible electrical conduit is recommended whenever vibration transmission may create a noise problem within the structure.
12.3 High Voltage Ground Ground the outdoor unit per national, state, and local code requirements.

Section 13. Start Up
13.1 System Start Up STEP 1 – Ensure Sections 7 through 12 have been completed. STEP 2 – Set System Thermostat to OFF. STEP 3 – Turn on disconnect(s) to apply power to the indoor and outdoor units. STEP 4 – Wait one (1) hour before starting the unit if compressor crankcase heater accessory is used and the Outdoor Ambient is below 70ºF. STEP 5 – Set system thermostat to ON.

Section 14. System Charge Adjustment
14.1 Temperature Measurements
STEP 1 – Check the outdoor temperatures.
Subcooling (in cooling mode) is the only recommended method of charging above 55º F ambient outdoor temperature. See Section 14.2.
For outdoor temperatures below 55º F, see Section 14.3. Note: It is important to return in the spring or summer to accurately charge the system in the cooling mode when outdoor ambient temperature is above 55º F.

For best results the indoor temperature should be kept between 70º F to 80º F. 10

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14.2 Subcooling Charging in Cooling (Above 55º F Outdoor Temp.) STEP 1 – Use the refrigerant line total length and lift measurements from Section 5.3.
Total Line Length = __ Ft.
LIFT
Vertical Change (Lift) = __ Ft.

STEP 2 – Determine the final subcooling value using total Line Length and Lift measured in STEP 1 and the charts below.

024N Models

036N Models

REFRIGERANT LINE LIFT (FT)

SUBCOOL CHARGING CHART CORRECTIONS TABLE (FOR LINE LENGTH AND RISE)

50 40 30 25 15 10
0 20

1° Add 1°
Use Design Subcooling

Add 2° Add 1°

30 40 50 60 70 80 90 100 110 120 130 140 150 TOTAL REFRIGERANT LINE LENGTH (FT) – [ includes lift ]

REFRIGERANT LINE LIFT (FT)

SUBCOOL CHARGING CHART CORRECTIONS TABLE (FOR LINE LENGTH AND RISE)

50 40 30 25 15 10
0 20

4°

Add 1°

Add 2°

Add 1°

Use Design Subcooling 1°

30 40 50 60 70 80 90 100 110 120 130 140 150 TOTAL REFRIGERANT LINE LENGTH (FT) – [ includes lift ]

048N Models

060N Models

REFRIGERANT LINE LIFT (FT)

SUBCOOL CHARGING CHART CORRECTIONS TABLE (FOR LINE LENGTH AND RISE)

50 40 30 25 15 10
0 20

1° 1° Add 1°
Use Design Subcooling

Add 4° Add 2°
Add 1°

30 40 50 60 70 80 90 100 110 120 130 140 150 TOTAL REFRIGERANT LINE LENGTH (FT) – [ includes lift ]

REFRIGERANT LINE LIFT (FT)

SUBCOOL CHARGING CHART CORRECTIONS TABLE (FOR LINE LENGTH AND RISE)

50 40 30 25 15 10
0 20

1° 1°
Use Design Subcooling

Add 4°
Add 2° Add 1°

Add 1° 1°
30 40 50 60 70 80 90 100 110 120 130 140 150 TOTAL REFRIGERANT LINE LENGTH (FT) – [ includes lift ]

Design Subcooling Value = __º F
(from nameplate)

Subcooling Correction = __º F

Final Subcooling Value = __º F

STEP 3 – Stabilize the system by operating for a minimum of 20 minutes. At startup, or whenever charge is removed or added, the system must be operated for a minimum of 20 minutes to stabilize before accurate measurements can be made.
STEP 4 – Measure the liquid line temperature and pressure at the outdoor unit’s service valve. Measured Liquid Line Temp = __ º F Liquid Gage Pressure = __ PSIG Final Subcooling Value = __ º F
STEP 5 – Use the final subcooling value, refrigerant temperature and pressure from STEP 4, to determine the proper liquid gage pressure using Table 14.2.
Example: Assume a 12º F Final Subcooling value and liquid temp of 90º F. 1. Locate 12º F Final Subcooling in Table 14.2. 2. Locate the Liquid Temperarature (90º F) in the left column. 3. The Liquid Gage Pressure should be approximately 327 PSIG. (This is the shown as the intersection of the
Final Subcooling column and the Liquid Temperature row in Table 14.2.)

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11

Table 14.2

R-410A REFRIGERANT CHARGING CHART

LIQUID
TEMP
(°F)

FINAL SUBCOOLING (°F)
8 9 10 11 12 13 14
LIQUID GAGE PRESSURE (PSI)

55 179 182 185 188 191 195 198

60 195 198 201 204 208 211 215

107 °F

65 211 215 218 222 225 229 232

70 229 232 236 240 243 247 251

75 247 251 255 259 263 267 271

80 267 271 275 279 283 287 291

85 287 291 296 300 304 309 313

90 309 313 318 322 327 331 336

95 331 336 341 346 351 355 360

100 355 360 365 370 376 381 386

105 381 386 391 396 402 407 413

110 407 413 418 424 429 435 441

115 435 441 446 452 458 464 470

120 464 470 476 482 488 495 501

125 495 501 507 514 520 527 533

From Dwg. D154557P01 Rev. 3

STEP 6 – Adjust refrigerant level to attain proper gage pressure. Add refrigerant if the Liquid Gage Pressure is lower than the chart value.
1. Connect gages to refrigerant bottle and unit as illustrated. 2. Purge all hoses. 3. Open bottle. 4. Stop adding refrigerant when liquid line temperature and Liquid Gage Pressure matches the charging chart
Final Subcooling value. Recover refrigerant if the Liquid Gage Pressure is higher than the chart value.
STEP 7 – Stabilize the system.
1. Wait 20 minutes for the system condition to stabilize between adjustments. Note: When the Liquid Line Temperature and Gage Pressure approximately match the chart, the system is properly charged.
2. Remove gages. 3. Replace service port caps to prevent leaks. Tighten finger tight plus an additional 1/6 turn.
STEP 8 – Verify typical performance. Refer to System Pressure Curves at the end of this document to verify typical performance.

12

SUCTION PRESSURE (PSIG)

DISCHARGE PRESSURE (PSIG)

(Example only)

Cooling @ 1450 SCFM

Heating @ 1350 SCFM

550 500 450

INDOOR ENTERING WET BULB CURVES TOP TO BOTTOM 71, 67, 63 AND 59 DEG F.

400

350 (4)

(3)

300

250

(1) 200

40

60

80

100

(2) 120

500 450

INDOOR ENTERING DRY BULB CURVES TOP TO BOTTOM 80, 70, AND 60 DEG F.

400

350

300

250

200

-5

5

15 25 35 45 55 65

OUTDOOR TEMPERATURE (Degree F)

170 165 160 155

INDOOR ENTERING WET BULB CURVES TOP TO BOTTOM 71, 67, 63 AND 59 DEG F.

150

145 (5) 140

(3)

135

130

125

120

115

(1)

110

40

60

80

100

(2) 120

140 130 120 110

INDOOR ENTERING DRY BULB CURVES TOP TO BOTTOM 80, 70, AND 60 DEG F.

100

90

80

70

60

50

40

30

-5

5

15 25 35 45 55 65

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STEP 9 – Record System Information for reference.
Record system pressures and temperatures after charging is complete.
Outdoor model number = _____
Measured Outdoor Ambient = __ º F
Measured Indoor Ambient = __ º F
Measured Liquid Line Temp = __ º F

Measured Suction Line Temp = __ º F Liquid Gage Pressure = __ PSIG Suction Gage Pressure = __ PSIG

Subcooling Charging Below 55º F Outdoor Temp. (In Heating Only)
The Subcooling Charging method in cooling is not recommended below 55º F outdoor temperature.
The only recommended method of charging at outdoor temperatures below 55º F is weighing in the charge in heating mode.

STEP 1 – Determine additional charge.
Note: The nameplate charge value represents the amount of refrigerant shipped in the outdoor unit and is compatible with 10 feet of AHRI rated refrigerant lines and the smallest AHRI rated coil.
Using the method below, find the charge associated with the additional length of tubing above 10 ft. and record it below.
Calculating Charge Using the Weigh-In Method
STEP 1 – Measure in feet the distance between the outdoor unit and the indoor unit. (Include the entire length of the line from the service valve to the IDU.) Subtract 10 ft from this entire length and record on line 1.
STEP 2 – Enter the charge multiplier (0.6 oz/ft). Each linear foot of interconnecting tubing requires the addition of 0.6 oz of refrigerant.
STEP 3 – Multiply the total length of refrigerant tubing (Line 1) times the value on Step 2. Record the result on Line 3 of the Worksheet.
STEP 4 – This is the amount of refrigerant to weigh-in prior to opening the service valves.
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Weigh-In Method can be used for the initial installation, or anytime a system charge is being replaced. Weigh-In Method can also be used when power is not available to the equipment site or operating conditions (indoor/outdoor temperatures) are not in range to verify with the subcooling charging method.

1. Total Line length (ft) ­ 10 ft __

2. Charge multiplier

x _0.6 oz___

3. Step 1 x Step 2

= _____

4. Refrigerant (oz)

= _____

13

STEP 2 – Stabilize the system by operating for a minimum of 20 minutes. At startup, or whenever charge is removed or added, the system must be operated for a minimum of 20 minutes to stabilize before accurate measurements can be made. STEP 3 – Check the liquid line temperature and liquid gage pressure to obtain a minimum of 10º subcooling in heating mode. Measured Liquid Line Temp = __ º F Liquid Gage Pressure = __ PSIG STEP 4 – Add charge if a minimum of 10º subcooling is not obtained with the namplate charge plus additional charge previously added. STEP 5 – Return to site for adjustment. Important: Return in the spring or summer to accurately charge the system in the cooling mode with outdoor ambient above 55º F.
Section 15. Checkout Procedures

Operational And Checkout Procedures

Final phases of this installation are the unit Operational and Checkout Procedures. To obtain proper performance, all units must be operated and charge adjustments made.

Important: Perform a final unit inspection to be sure that factory tubing has not shifted during shipment. Adjust tubing if necessary so tubes do not rub against each other when the unit runs. Also be sure that wiring connections are tight and properly secured.

CHECKOUT PROCEDURE
After installation has been completed, it is recommended that the entire system be checked against the following list:

1. Leak check refrigerant lines. …………………………………. [ ] 2. Properly insulate suction lines and fittings……………….. [ ] 3. Properly secure and isolate all refrigerant lines………… [ ] 4. Seal passages through masonry. If mortar is used, prevent mortar from coming into direct contact with copper tubing. …………………….. [ ] 5. Verify that all electrical connections are tight……………. [ ] 6. Observe outdoor fan during on cycle for clearance and smooth operation…………………………………………… [ ]

7. Be sure that indoor coil drain line drains freely. Pour water into drain pan………………………………………………………. [ ] 8. Be sure that supply registers and return grilles are open and unobstructed…………………………………………………. [ ] 9. Be sure that a return air filter is installed…………………. [ ] 10. Be sure that the correct airflow setting is used. (Indoor blower motor) …………………………………………… [ ] 11. Operate complete system in each mode to ensure safe operation…………………………………………… [ ]

14

18-AC104D1-1G-EN

Section 16. Defrost Control

The demand defrost control measures heat pump outdoor ambient temperature with a sensor located outside the outdoor coil. A second sensor located on the outdoor coil is used to measure the coil temperature. The difference between the ambient and the colder coil temperature is the difference or delta-T measurement. This delta-T measurement is representative of the operating state and relative capacity of the heat pump system. By measuring the change in delta-T, we can determine the need for defrost. The coil sensor also serves to sense outdoor coil temperature for termination of the defrost cycle.

Pin Identification
1. TEST_COMMON (Shorting any of the other pins to this pin causes the function of the other pin to be executed. Leaving this pin open results in the normal mode of operation.)
2. TST = Test (Shorting TEST_COMMON to this pin speeds up all defrost board timings.)
3. FRC_DFT = Forced Defrost (Short TEST_COMMON to this pin for two [2] seconds to initiate a forced defrost. Remove the short after defrost initiates.)

Termination Temperature Defrost controls have a selectable termination temperature. As shipped, defrost will terminate at 47°F. For a higher termination temperature, cut Jumper J2 to achieve 70°F when at or below 30°F ambient.

Defrost Control Checkout Normal operation requires:
a. LED on board flashing 1 time/second.
b. 24V AC between R & B.

Fault Identification A fault condition is indicated by the flashing light on the defrost control inside the heat pump control box.

c. 24V AC between Y & B with unit operating.
d. Defrost initiation when FRC_DFT pin is shorted to TEST_COMMON pin.

In normal operation, the defrost control light will flash once each second. If the light is flashing more than once per second or not at all, refer to the Defrost Checkout sheet found with the service information in the control box.

If a defrost control problem is suspected, refer to the service information in control box.

DEFROST TERMINATION TEMPERATU RE

For 024N, 048N & 060N Models

Defrost Termination Temperatures

Outdoor Temp.

Termination Temperature

Defrost controls have a selectable termination temperature. Cutting jumper J2 (shown below) will achieve a termination temperature of 70° when the ambient temperature is below 30° (see table at left).

As Shipped

22°F 10°F­22°F 6°F­10°F

47°F ODT + 25°F
35°F

Defrost Board Detail

Cut

30°F

Jumper 2 6°F­30°F

< 6°F

All

0°F

5°F

47°F 70°F 12 min. or 35°F every 3 hrs. Outdoor unit will be turned OFF Resume outdoor unit operation

JUMPER 2 TEST PINS

J1 J2 J3

FRC_DFT

U1

For 036N Models only

TEST_COMMON

Defrost Termination Temperatures

TST

Outdoor Temperature

Termination Temperature

As Shipped

22°F 10°F­22°F 6°F­10°F

47°F ODT + 25°F
35°F

Cut Jumper 2

30°F 6°F­30°F

47°F 70°F

All

< 6°F

12 min. or 35°F every 3 hrs.

18-AC104D1-1G-EN

15

J1 To Coil on EEV

EEV CONTROL BOARD TEST POINTS

OPEN

Test Pins
OPEN CLOSE TEST

TEST

J6 See Table 3
Control Input 24 VAC Stage/Mode

CLOSE
DC V TEST POINT

STATUS LED (Green)
Fault LED (Red)
J7
See Table 2
Suction Line Pressure Transducer Input
J10
See Table 1
Suction Line Temperature Sensor Input

Note: Close Valve and Open Valve Tests are active in any mode of operation

Test Pins: OPEN, CLOSE, TEST (See EEV Board drawing for locations)

Close Valve Test – Touch CLOSE pin to TEST pin.
EEV drives closed (5 seconds max) and stays closed for 1.5 minutes (90 seconds). 1) Status LED will be flashing. 2) Gauges should indicate suction pressure dropping. · Valve is working. · LPCO may trip.
Note: The Close Valve Test will exit after 1.5 minutes (90 seconds) and will not reinitiate (requires a break and make to initialize). To clear faults stored in memory, apply a jumper between Close and Test pins for 10 seconds.

Open Valve Test – Touch OPEN pin to TEST pin.
EEV drives open (5 sec max) and stays open for 30 seconds. 1) Status LED will be flashing. 2) Temperature probe should indicate superheat falling. · Valve is working.
Note: If jumper is left on pins, the OPEN VALVE TEST will be cleared after 30 seconds and will not reinitiate (requires a break and make to reinitialize).

Exit Test Mode – The Open Valve Test or Closed Valve Test can be cancelled by jumping to the opposite mode Test pin.
The system will return to normal super heat control.

Test mode will cancel if: 1) Unit enters Defrost 2) Y1 input is lost
16

18-AC104D1-1G-EN

TABLE 1 Suction Line Temperature Sensor – J10

Temp °F Temp °C

0

-17.8

5

-15.0

10

-12.2

15

-9.4

20

-6.7

25

-3.9

30

-1.1

35

1.7

40

4.4

45

7.2

50

10.0

55

12.8

60

15.6

65

18.3

70

21.1

75

23.9

80

26.7

85

29.4

90

32.2

95

35.0

100

37.8

105

40.6

110

43.3

115

46.1

120

48.9

125

51.7

130

54.4

135

57.2

136

57.8

137

58.3

138

58.9

139

59.4

140

60.0

141

60.6

142

61.1

143

61.7

144

62.2

145

62.8

146

63.3

147

63.9

148

64.4

149

65.0

150

65.6

THERMISTOR RESISTANCE (OHMS)
83247 71108 60916 52333 45076 38927 33703 29253 25452 22198 19405 17002 14930 13138 11586 10238 9065 8043 7150 6368 5682 5079 4548 4079 3665 3298 2972 2683 2629 2576 2525 2474 2425 2377 2330 2284 2239 2195 2153 2111 2070 2030 1990

Volts DC at Plug J10
(pin to pin)
3.87 3.73 3.57 3.41 3.25 3.08 2.91 2.73 2.56 2.39 2.22 2.06 1.90 1.75 1.61 1.48 1.36 1.24 1.14 1.04 0.95 0.86 0.79 0.72 0.66 0.60 0.54 0.50 0.49 0.48 0.47 0.46 0.45 0.45 0.44 0.43 0.42 0.41 0.41 0.40 0.39 0.39 0.38

TABLE 2
Suction Line Pressure Transducer – J7 Voltage to pressure reference Chart

Pressure (PSIG)
34 41 51 60 70 80 89 99 108 118 130 140 147 159 169 178 188 198

Volts DC at plug J7 (to test point common)
0.8 0.9 1.0 1.1 1.2 1.3 1.4 1.5 1.6 1.7 1.8 1.9 2.0 2.1 2.2 2.3 2.4 2.5

Suction Line Pressure Transducer

Suction Line Temperature Sensor

18-AC104D1-1G-EN

17

ELECTRONIC EXPANSION VALVE (EEV) CONTROL BOARD

Status LED (Green)
On – Control has power
Flashing Fast – Control is driving valve (5 seconds max drive time)
Flashing Pattern – See Table 6.

OPEN CLOSE

TEST

STATUS LED (Green)
Fault LED (Red)

EEV control

Heat

Standby 1st Stage 2nd Stage

ON ON OFF ON

Cool

Standby OFF
1st Stage ON 2nd Stage ON OFF ON

1 sec

TABLE 3 Control Input and Status LED – J6
STATUS LED

OFF OFF
ON

ON Continuous

ON

ON

ON

OFF OFF

OFF

2 sec

3 sec

OFF OFF
ON
4 sec

24 VAC at plug J6
B to R B to R & Y1 B to R, Y1 & Y2
B to R & O B to R, Y1 & O B to R, Y1, Y2 & O

Fault LED (Red)

LED Color
Red

EEV Fault LED
OFF Standby

Description

1 Flash Coil has an open circuit or intermittent short (Replace Coil)

2 Flash Control has detected an internal failure (Replace EEV control board)

3 Flash Suction Pressure Transducer input is out of range (Replace transducer) (1)

4 Flash Suction Temperature Sensor input is out of range (Replace sensor) (1)

5 Flash Coil has short circuit (Replace Coil) (2)
The following may require additional diagnostics

6 Flash 7 Flash 8 Flash 9 Flash

Valve is not responding to a position change command (Possible stuck valve) Valve is responding but system is not performing properly (Low charge or restriction) Compressor is not pumping (3) Low superheat in Cooling Mode (Indoor TXV stuck open or ID Fan failure)

10 Flash Not used at this time

EEV Fault Codes EEV not used on all models (1) Valve will close and LPCO will trip Notes: (2) Power supply will shut down to protect board (3) Monitor superheat and pressure: <3′ SH for 5 minutes with valve @ minimum position, Monitor off-cycle pressure and compare to next on-cycle for pressure drop within 60 seconds
Printed from D802247P01 Rev08 Fault Storing/CleAHRIng:
Faults 6-9 will be stored in non-volatile memory. See Close Valve Test for fault clearing procedure. Faults 1-5 will clear with a power cycle.

18

18-AC104D1-1G-EN

TROUBLESHOOTING THE EEV
The Electronic Expansion Valve (EEV) installed in this heat pump is designed to control superheat entering the compressor when the system is running in mechanical heating mode. During cooling mode, refrigerant flow reverses through the outdoor EEV and superheat is controlled by the expansion device in the indoor unit. Therefore, any operational problems observed in cooling mode are not caused by the outdoor EEV.
The following flow chart was designed to assist in troubleshooting the EEV.
Note: The EEV closes with every OFF cycle in the heating mode of operation. During Defrost and in the cooling mode of operation, the EEV will drive to full open. An audible sound can be heard when valve is changing positions.

System is pumping down in heat mode

EEV is not sensing that the compressor is ON and in the Heat Mode
1. Check plug and harness to J6 2. Verify 24VAC at Y1 and/or Y2 inputs to EEV control J6 are present (not “O”) See
Table 3 in page 19.

System is very low on charge 1. Check charge

Low superheat (flooding) in heating mode
High superheat (low suction pressure) in
heating mode
EEV Hunting (Suction pressure moves
up & down)
18-AC104D1-1G-EN

EEV valve is stuck open 1. See for Close Valve Test

EEV valve is stuck closed 1. See for Open Valve Test

Sensors are out of calibration 1. Verify sensors are accurate. See Table 1
& 2 in page 18

System is low on charge 1. Check charge
Sensors are out of calibration 1. Verify sensors are accurate. See Table 1
& 2 in page 18

Sensor are out of calibration 1. Verify sensors are accurate. See Table 1
& 2 page 18

EEV valve is stuck closed 1. See for Open Valve Test

Verify temperature sensor is clipped tight to suction line and insulated

Verify Outdoor Unit: 1. Is free and clear of ice and debris
2. Has adequate clearance 3. Distributor tubes are not bent or kinked
19

Section 17. Troubleshooting
Compressor fails to start Contactor check

Is contactor energized? (contacts closed)
NO
Check for 24 volts AC across contactor coil

YES

Go To: Compressor won’t run

Is voltage present at contactor coil?
NO
Check control transformer and
control fuse

YES

Replace contactor

Is the control transformer and fuse good?
NO
Repair or replace transformer or fuse. Investigate cause for failure (possible short in
field wiring)

YES

Jumper R to Y low voltage terminals at thermostat sub
base.

Does the contactor energize?
NO

YES

Replace the room thermostat

Repair or replace connecting wiring

20

18-AC104D1-1G-EN

Compressor won’t run Contactor is closed

Check for high voltage to contactor

Is high voltage present YES at T1 and T2 ?
NO
Check power supply from disconnect and/or breaker panel.

Check for open IOL (Internal Overload) Check resistance of C to S and C to R
Does the resistance check
show an open circuit from C to S
or C to R?

YES

Allow compressor time to cool and
re-test

NO
Check for open windings.

Does a resistance check
show an open circuit between R and S?

YES

Replace the compressor

NO
Check for locked rotor

Is voltage present at C to S and C to R with locked rotor amps on C?
NO
Check wiring to compressor C, S and R

YES

Check StartCapacitor and Relay (if present) and Run Capacitor

Do the start components and
run capacitor check good?

YES

NO
Replace start components and/ or run capacitor

Replace the compressor

18-AC104D1-1G-EN

21

Section 18. Wiring Diagrams

Wiring Diagram ­ 024N Models

22

18-AC104D1-1G-EN

18-AC104D1-1G-EN

Wiring Diagram ­ 036N, 048N & 060N Models

23

24

18-AC104D1-1G-EN

Section 19. Pressure Curves

COOLING PERFORMANCE CAN BE CHECKED WHEN THE OUTDOOR TEMP IS ABOVE 65 DEG F. TO CHECK COOLING PERFORMANCE, SELECT THE PROPER INDOOR CFM, ALLOW PRESSURES TO STABILIZE. MEASURE INDOOR WET BULB TEMPERATURE, OUTDOOR TEMPERATURE, DISCHARGE AND SUCTION PRESSURES. ON THE PLOTS LOCATE OUTDOOR TEMPERATURE (1); LOCATE INDOOR WET BULB (2); FIND INTERSECTION OF OD TEMP. & ID W.B. (3); READ DISCHARGE OR SUCTION PRESSURE IN LEFT COLUMN (4).

EXAMPLE: (1) OUTDOOR TEMP. 82 F. (2) INDOOR WET BULB 67 F. (3) AT INTERSECTION
(4) DISCHARGE PRESSURE @ 740 CFM IS 291 PSIG.
(5) SUCTION PRESSURE @ 740 CFM IS 154 PSIG.

ACTUAL: DISCHARGE PRESSURE SHOULD BE +/- 10 PSIG OF CHART SUCTION PRESSURE SHOULD BE +/- 3 PSIG OF CHART

DISCHARGE PRESSURE (PSIG)

PRESSURE CURVES FOR 4TWR6024N1

TAM7A0B30H21

TAM7A0B30H21

Cooling with Thermal Expansion Valve

INDOOR ENTERING WET BULB CURVES TOP TO BOTTOM

500

71, 67, 63 AND 59 DEG F.
500

Heating with Thermal Expansion Valve

INDOOR ENTERING DRY BULB CURVES TOP TO BOTTOM

500

80, 70, AND 60 DEG F.
500

2ND STAGE 450

1ST STAGE 450

(2)
450

2ND STAGE

1ST STAGE 450

400

400

400

400

350

350

350

350

300

300 (4)

(3)

300

300

250

250

250

250

200

200

(1)

200

200

40 60 80 100 120 40 60 80 100 120

-5 5 15 25 35 45 55 65 -5 5 15 25 35 45 55 65

OUTDOOR TEMPERATURE (Degree F)

180 170 160 150 140 130 120
40

INDOOR

ENTERING 71,

6W7E, T63B1AU8NL0DB

CURVES TOP 59 DEG F.

TO

BOTTOM

2ND STAGE

170

1ST STAGE

160
(5)

150

(3)

150 140 130
(2) 120
110 100
90

INDOOR

ENTERING DRY 80, 70,

AB1NU5DL0B60CUDREGVEFS.

TOP

TO

BOTTOM

2ND STAGE

140

130

1ST STAGE

120

110

100

90

140

80

80

70

70

130

60

60

(1)

50

50

120

40

40

60 80 100 120 40 60 80 100 120

-5 5 15 25 35 45 55 65 -5 5 15 25 35 45 55 65

OUTDOOR TEMPERATURE (Degree F)

SUCTION PRESSURE (PSIG)

18-AC104D1-1G-EN

25

DISCHARGE PRESSURE (PSIG)

PRESSURE CURVES FOR 4TWR6036N1

TAM7A0C36H31

TAM7A0C36H31

Cooling with Expansion Valve

INDOOR ENTERING WET BULB CURVES TOP TO BOTTOM

550

71, 67, 63 AND 59 DEG F.
550

Heating with Expansion Valve

INDOOR ENTERING DRY BULB CURVES TOP TO BOTTOM

400

80, 70, AND 60 DEG F.
400

500

2ND STAGE

450

500

1ST STAGE

450

2ND STAGE
(2) 350

1ST STAGE 350

400

400

300

300

350

350

300

300 (4)

(3)

250

250

250

250

(1)

200

200

200

200

40 60 80 100 120 40 60 80 100 120

-5 5 15 25 35 45 55 65 -5 5 15 25 35 45 55 65

OUTDOOR TEMPERATURE (Degree F)

190 180 170 160 150 140 130 120
40

INDOOR

ENTERING 71,

6W7E, T63B1AU9NL0DB

CURVES TOP 59 DEG F.

TO

BOTTOM

2ND STAGE

180

1ST STAGE

160 150

INDOOR

ENTERING DRY 80, 70,

A1BNU6DL0B60CUDREGVEFS.

TOP

TO

BOTTOM

150

140 2ND STAGE

140

1ST STAGE

130

130

170

120

120

(2) 110

110

160

(5)

(3)

150

100 90

100 90

80

80

140

70

70

60

60

130

50

50

(1)

40

40

120

30

30

60 80 100 120 40 60 80 100 120

-5 5 15 25 35 45 55 65 -5 5 15 25 35 45 55 65

OUTDOOR TEMPERATURE (Degree F)

SUCTION PRESSURE (PSIG)

DISCHARGE PRESSURE (PSIG)

PRESSURE CURVES FOR 4TWR6048N1

TAM7A0C48H41

TAM7A0C48H41

550

Cooling with Expansion Valve
INDOOR ENTERING WET BULB CURVES TOP TO BOTTOM 71, 67, 63 AND 59 DEG F.
550

Heating with Expansion Valve

INDOOR ENTERING DRY BULB CURVES TOP TO BOTTOM

400

80, 70, AND 60 DEG F.
400

500

2ND STAGE

450

500

1ST STAGE

450

2ND STAGE
(2)
350

1ST STAGE 350

400

400

300

300

350

350

300

300 (4)

(3)

250

250

250

250

(1)

200

200

200

200

40 60 80 100 120 40 60 80 100 120

-5 5 15 25 35 45 55 65 -5 5 15 25 35 45 55 65

OUTDOOR TEMPERATURE (Degree F)

180 170 160 150 140 130 120 110
40

INDOOR

ENTERING 71,

6W7E, T63B1AU8NL0DB

CURVES TOP 59 DEG F.

TO

BOTTOM

2ND STAGE

170

1ST STAGE

140

INDOOR

ENTERING DRY 80, 70,

A1BNU4DL0B60CUDREGVEFS.

TOP

TO

BOTTOM

130

120

2ND STAGE

130

120

1ST STAGE

160

(2) 110

110

100

100

150 (5)

(3)

90

90

140

80

80

70

70

130

60

60

120

50

50

(1)

40

40

110

30

30

60 80 100 120 40 60 80 100 120

-5 5 15 25 35 45 55 65 -5 5 15 25 35 45 55 65

OUTDOOR TEMPERATURE (Degree F)

SUCTION PRESSURE (PSIG)

26

18-AC104D1-1G-EN

DISCHARGE PRESSURE (PSIG)

PRESSURE CURVES FOR 4TWR6060N1

TAM7B0C60H51

TAM7B0C60H51

Cooling with Expansion Valve

INDOOR ENTERING WET BULB CURVES TOP TO BOTTOM

550

71, 67, 63 AND 59 DEG F.
550

Heating with Expansion Valve

INDOOR ENTERING DRY BULB CURVES TOP TO BOTTOM

400

80, 70, AND 60 DEG F.
400

500

2ND STAGE

450

500

1ST STAGE

450

2ND STAGE
(2)
350

1ST STAGE 350

400

400

300

300

350

350

300

300 (4)

(3)

250

250

250

250

(1)

200

200

200

200

40 60 80 100 120 40 60 80 100 120

-5 5 15 25 35 45 55 65 -5 5 15 25 35 45 55 65

OUTDOOR TEMPERATURE (Degree F)

180 170 160 150 140 130 120 110
40

INDOOR

ENTERING 71,

6W7E, T63B1AU8NL0DB

CURVES TOP 59 DEG F.

TO

BOTTOM

2ND STAGE

170

1ST STAGE

140

INDOOR

ENTERING DRY 80, 70,

A1BNU4DL0B60CUDREGVEFS.

TOP

TO

BOTTOM

130 120 2ND STAGE

130

120

1ST STAGE

160

110

110

(2) 100

100

150

(5)

(3)

140

90 80

90 80

70

70

130

60

60

120

50

50

(1)

40

40

110

30

30

60 80 100 120 40 60 80 100 120

-5 5 15 25 35 45 55 65 -5 5 15 25 35 45 55 65

OUTDOOR TEMPERATURE (Degree F)

SUCTION PRESSURE (PSIG)

18-AC104D1-1G-EN

27

Section 20. Refrigerant Circuit (only for reference)
Heating Refrigeration Cycle

Cooling Refrigeration Cycle

Printed from D158967
NOTE: 4TWR6036N unit does not have suction accumulator.

Trane – by Trane Technologies (NYSE: TT), a global climate innovator – creates comfortable, energy-efficient indoor environments for commercial and residential applications. For more information, please visit trane.com or tranetechnologies.com.
18-AC104D1-1G-EN 12 Apr 2023 Supersedes 18-AC104D1-1F-EN (June 2022)

The AHRI Certified mark indicates Trane U.S. Inc. participation in the AHRI Certification program. For verification of individual certified products, go to ahridirectory.org. Trane has a policy of continuous data improvement and it reserves the right to change design and specifications without notice. We are committed to using environmentally conscious print practices.
© 2023 Trane

References

• DWG.no - DWG Cad Software | DWG View | DWG til PDF | Norsk nettside som går gjennom nyheter og muligheter innen 2D og 3D design
• Trane Heating & Air Conditioning

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