Carrier Refrigerator 69NT20 531 300 User Manual

Carrier

Transicold

Container

Refrigeration

Model 69NT20-531-300

Streamline Scroll

Operation

& Service

T-309 Rev A

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SAFETY SUMMARY

GENERAL SAFETY NOTICES

The following general safety notices supplement the specific warnings and cautions appearing elsewhere in this

manual. They are recommended precautions that must be understood and applied during operation and maintenance

of the equipment covered herein. The general safety notices are presented in thefollowing threesections labeled: First

Aid, Operating Precautions and Maintenance Precautions. A listing of the specific warnings and cautions appearing

elsewhere in the manual follows the general safety notices.

FIRST AID

An injury, no matterhowslight, should nevergo unattended. Always obtain first aid ormedical attentionimmediately.

OPERATING PRECAUTIONS

Always wear safety glasses.

Keep hands, clothing and tools clear of the evaporator and condenser fans.

No work should beperformed on theunit until all circuit breakers, start-stop switches areturned off, and powersupply

is disconnected.

Always work in pairs. Never work on the equipment alone.

In case of severe vibration or unusual noise, stop the unit and investigate.

MAINTENANCE PRECAUTIONS

Beware of unannounced starting of the evaporator and condenser fans. Do not open the condenser fan grille or

evaporator access panels before turning power off, disconnecting and securing the power plug.

Besurepoweris turned offbeforeworking on motors, controllers, solenoid valves and electrical control switches. Tag

circuit breaker and power supply to prevent accidental energizing of circuit.

Do not bypass any electrical safety devices, e.g. bridging an overload, or using any sort of jumper wires. Problems

with the system should be diagnosed, and any necessary repairs performed, by qualified service personnel.

When performing any arcwelding on theunit orcontainer, disconnect all wire harness connectors from the modules in

both control boxes. Do not remove wire harness from the modules unless you are grounded to the unit frame with a

static safe wrist strap.

In case of electrical fire, open circuit switch and extinguish with CO₂(never use water).

UNIT LABEL IDENTIFICATION

To help identify the label hazards on the unit and explain the level of awareness each one carries, an explanation is

given with the appropriate consequences:

DANGER -- means an immediate hazard which WILL result in severe personal injury or death.

WARNING -- means to warn against hazards or unsafe conditions which COULD result in severe personal injury or

death.

CAUTION -- means to warn against potential hazard or unsafe practice which could result in minor personal injury,

product or property damage.

SPECIFIC WARNING AND CAUTION STATEMENTS

The statements listed below are applicable to the refrigeration unit and appear elsewhere in this manual. These

recommended precautions must be understood and applied during operation and maintenance of the equipment

covered herein.

WARNING

Beware of unannounced starting of the evaporator and condenser fans. The unit may cycle the fans

and compressor unexpectedly as control requirements dictate.

WARNING

Do not attempt to remove power plug(s) before turning OFF start-stop switch (ST), unit circuit break-

er(s) and external power source.

WARNING

Make sure the power plugs are clean and dry before connecting to any power receptacle.

T-309

Safety-1

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WARNING

Make sure that the unit circuit breaker(s) (CB-1 & CB-2) and the START-STOP switch (ST) are in the

“O” (OFF) position before connecting to any electrical power source.

WARNING

Never use air for leak testing. It has been determined that pressurized, mixtures of refrigerant and air

can undergo combustion when exposed to an ignition source.

WARNING

Make sure power to the unit is OFF and power plug disconnected before replacing the compressor.

WARNING

Before disassembly of the compressor make sure to relieve the internal pressure very carefully by

slightly loosening the couplings to break the seal.

WARNING

Oakite No. 32 is an acid. Be sure that the acid is slowly added to the water. DO NOT PUT WATER

INTO THE ACID -- this will cause spattering and excessive heat.

WARNING

Wear rubber gloves and wash the solution from the skin immediately if accidental contact occurs. Do

not allow the solution to splash onto concrete.

WARNING

Always turn OFF the unit circuit breakers (CB-1 & CB-2) and disconnect main power supply before

working on moving parts.

WARNING

Make sure power to the unit is OFF and power plug disconnected before removing capacitor(s).

WARNING

With power OFF discharge the capacitor before disconnecting the circuit wiring.

WARNING

Do not use a nitrogen cylinder without a pressure regulator. Do not use oxygen in or near a refrigera-

tion system as an explosion may occur.

WARNING

Do not open the condenser fan grille before turning power OFF and disconnecting power plug.

WARNING

The Unit Power Plug Must Be Disconnected To Remove Power From Circuit Breaker Cb1

CAUTION

Do not remove wire harnesses from controller modules unless you are grounded to the unit frame with

a static safe wrist strap.

CAUTION

Unplug all controller modulewireharness connectors beforeperforming arcweldingon anypart ofthe

container.

CAUTION

When condenser water flow is below 11 lpm (3 gpm) or when water-cooled operation is not in use, the

CFS switch MUST be set to position ”1” or the unit will not operate properly.

CAUTION

Pre-trip inspection should not be performed with critical temperature cargoes in the container.

T-309

Safety-2

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CAUTION

When Pre-Trip key is pressed, economy, dehumidification and bulb mode will be deactivated. At the

completion of Pre-Trip activity, economy, dehumidification and bulb mode must be reactivated.

CAUTION

When a failure occurs during automatic testing the unit will suspend operation awaiting operator in-

tervention.

CAUTION

When Pre--Trip test Auto 2 runs to completion without being interrupted, the unit will terminate pre-

trip and display “Auto 2” “end.” The unit will suspend operation until the user depresses the ENTER

key!

CAUTION

To prevent trapping liquid refrigerant in the manifold gauge set be sure set is brought to suction pres-

sure before disconnecting.

CAUTION

The scroll compressor achieves low suction pressure very quickly. Do not use the compressor to evacu-

ate the system below zero psig. Never operate the compressor with the suction or discharge service

valves closed (frontseated). Internal damage will result from operating the compressor in a deep vacu-

um.

CAUTION

Use only Carrier Transicold approved Polyol Ester Oil (POE) -- Mobil ST32 compressor oil with

R-134a. Buy in quantities ofone quart or smaller. When using this hygroscopicoil, immediately reseal.

Do not leave container of oil open or contamination will occur.

CAUTION

Take necessary steps (place plywood over coil or use sling on motor) to prevent motor from falling into

condenser coil.

CAUTION

DO NOT disassemble piston from NEW suction modulating valve powerhead assembly. Doing so may

result in damage to piston.

CAUTION

The unit must be OFF whenever a programming card is inserted or removed from the controller pro-

gramming port.

CAUTION

Do not allow moisture to enter wire splice area as this may affect the sensor resistance.

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Safety-3

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TABLE OF CONTENTS

PARAGRAPH NUMBER

Page

GENERAL SAFETY NOTICES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Safety-1

FIRST AID . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Safety-1

OPERATING PRECAUTIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Safety-1

MAINTENANCE PRECAUTIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Safety-1

UNIT LABEL IDENTIFICATION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Safety-1

SPECIFIC WARNING AND CAUTION STATEMENTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Safety-1

INTRODUCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.1 INTRODUCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.2 CONFIGURATION IDENTIFICATION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.3 OPTION DESCRIPTIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.3.1 Battery . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.3.2 Dehumidification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.3.3 Control Box . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.3.5 Pressure Readout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.3.6 Interrogator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.3.7 Remote Monitoring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.3.8 Communications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.3.9 Compressor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.3.10 Back Panels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.3.11 460 Volt Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.3.12 Cable Restraint . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.3.13 Upper Air (Fresh Air Make Up) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.3.14 Evaporator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.3.15 Evaporator Fan Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.3.16 Labels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.3.17 Plate Set . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.3.18 Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.3.19 Stepper Drive . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1.3.20 Condenser Grille . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2.1 GENERAL DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2.1.1 Refrigeration Unit -- Front Section . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2.1.2 Fresh Air Makeup Vent . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2.1.3 Evaporator Section . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2.1.4 Compressor Section . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2.1.5 Air Cooled Condenser Section . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2.1.6 Control Box Section . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2.1.7 Communications Interface Module . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2.2 REFRIGERATION SYSTEM DATA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2.3 ELECTRICAL DATA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2.4 SAFETY AND PROTECTIVE DEVICES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2.5 REFRIGERATION CIRCUIT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1-1

1-2

2-1

2-2

2-3

2-4

2-5

2-6

2-7

2-8

2-9

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TABLE OF CONTENTS (cont)

2.5.1 Standard Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2.5.2 Economized Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2.5.3 Unloaded Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

MICROPROCESSOR . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.1 TEMPERATURE CONTROL MICROPROCESSOR SYSTEM . . . . . . . . . . . . . . . . . . . . . . . . . .

3.1.1 Key Pad . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.1.2 Display Module . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.1.3 Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.2 CONTROLLER SOFTWARE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.2.1 Configuration Software (Configuration Variables) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.2.2 Operational Software (Function codes) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.3 MODES OF OPERATION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.3.1 Temperature Control -- Perishable Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.3.2 Defrost Interval . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.3.3 Failure Action . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.3.4 Generator Protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.3.5 Compressor High Temperature, Low Pressure Protection. . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.3.6 Perishable Mode -- Conventional . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.3.7 Perishable Mode -- Economy . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.3.8 Perishable Mode -- Dehumidification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.3.9 Perishable, Dehumidification -- Bulb Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.3.10 Temperature Control -- Frozen Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.3.11 Frozen Mode -- Conventional . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.4 CONTROLLER ALARMS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.5. UNIT PRE-TRIP DIAGNOSTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.6 DataCORDER . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.6.1 Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.6.2 DataCORDER Software . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3.6.3 Sensor Configuration (dCF02) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2-9

3-1

3-2

3-3

3-4

3-5

3-6

3-7

3-8

3.6.4 Logging Interval (dCF03) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-10

3.6.5 Thermistor Format (dCF04) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-10

3.6.6 Sampling Type (dCF05 & dCF06) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-10

3.6.7 Alarm Configuration (dCF07 -- dCF10) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-10

3.6.8 DataCORDER Power-Up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-10

3.6.9 Pre-Trip Data Recording . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-10

3.6.10 DataCORDER Communications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-10

3.6.11 USDA Cold Treatment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-11

3.6.12 USDA Cold Treatment Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-11

3.6.13 DataCORDER Alarms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-12

3.6.14 ISO Trip Header . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-12

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TABLE OF CONTENTS (cont)

OPERATION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4.1 INSPECTION (Before Starting) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4.2 CONNECT POWER . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4.2.1 Connection To 380/460 vac Power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4.3 ADJUST FRESH AIR MAKEUP VENT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4.3.1 Upper Fresh Air Makeup Vent . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4-1

4.4 CONNECT REMOTE MONITORING

RECEPTACLE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4-2

4-3

4-4

4-5

4.5 STARTING AND STOPPING INSTRUCTIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4.5.1 Starting the Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4.5.2 Stopping the Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4.6 START--UP INSPECTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4.6.1 Physical Inspection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4.6.2 Check Controller Function Codes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4.6.3 Complete Inspection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4.7 PRE-TRIP DIAGNOSIS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4.8 OBSERVE UNIT OPERATION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4.8.1 Probe Check . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4.9 SEQUENCE OF OPERATION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4.9.1 Sequence Of operation -- Compressor Phase Sequence . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4.9.2 Sequence Of Operation -- Perishable Mode Cooling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4.9.3 Sequence Of Operation --

Perishable Mode Heating . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4-6

5-1

5-2

5-3

5-4

5-5

4.9.4 Sequence Of operation -- Frozen Mode Cooling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

4.9.5 Sequence Of Operation -- Defrost . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

TROUBLESHOOTING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

5.1 UNIT WILL NOT START OR STARTS THEN STOPS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

5.2 UNIT OPERATES LONG OR CONTINUOUSLY IN COOLING . . . . . . . . . . . . . . . . . . . . . . . . .

5.3 UNIT RUNS BUT HAS INSUFFICIENT COOLING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

5.4 UNIT WILL NOT HEAT OR HAS INSUFFICIENT HEATING . . . . . . . . . . . . . . . . . . . . . . . . . .

5.5 UNIT WILL NOT TERMINATE HEATING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

5.6 UNIT WILL NOT DEFROST PROPERLY . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

5.7 ABNORMAL PRESSURES (COOLING) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

5.8 ABNORMAL NOISE OR VIBRATIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

5.9 CONTROLLER MALFUNCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

5.10 NO EVAPORATOR AIR FLOW OR RESTRICTED AIR FLOW . . . . . . . . . . . . . . . . . . . . . . . . .

5.11 THERMOSTATIC EXPANSION VALVE MALFUNCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

5.12 AUTOTRANSFORMER MALFUNCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

5.13 WATER-COOLED CONDENSER OR WATER PRESSURE SWITCH . . . . . . . . . . . . . . . . . . . .

5.14 COMPRESSOR OPERATING IN REVERSE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

5.15 ABNORMAL TEMPERATURES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

5.16 ABNORMAL CURRENTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

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TABLE OF CONTENTS (cont)

SERVICE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.1 SECTION LAYOUT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.2 SERVICE VALVES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.3. MANIFOLD GAUGE SET . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.4 PUMPING THE UNIT DOWN . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.5 REFRIGERANT LEAK CHECKING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.6 EVACUATION AND DEHYDRATION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.6.1 General . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.6.2 Preparation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.6.3 Procedure - Complete system . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.6.4 Procedure - Partial System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.7 REFRIGERANT CHARGE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.7.1 Checking the Refrigerant Charge . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.7.2 Adding Refrigerant to System (Full Charge) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.7.3 Adding Refrigerant to System (Partial Charge) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.8 COMPRESSOR -- Model RSH105 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.8.1 Removal and Replacement of Compressor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.9 COMPRESSOR OIL LEVEL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.10 HIGH PRESSURE SWITCH . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.10.1 Replacing High Pressure Switch . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.10.2 Checking High Pressure Switch . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.11 CONDENSER COIL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.12 CONDENSER FAN AND MOTOR ASSEMBLY . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.13 FILTER-DRIER . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.14 EXPANSION VALVES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.14.1 Checking Superheat. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.14.2 Valve Replacement . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6.15 EVAPORATOR COIL AND HEATER

6-1

6-2

6-3

6-4

6-5

6-7

6-8

6-9

ASSEMBLY . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-10

6.15.1 Evaporator Coil Replacement . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-10

6.15.2 Evaporator Heater Replacement . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-10

6.16 ECONOMIZER, UNLOADER, LIQUID INJECTION AND OIL RETURN SOLENOID VALVE 6-11

6.17 EVAPORATOR FAN AND MOTOR ASSEMBLY . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-11

6.17.1 Replacing The Evaporator Fan Assembly . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-12

6.18 EVAPORATOR FAN MOTOR CAPACITORS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-12

6.18.1 When To Check For A Defective Capacitor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-12

6.18.2 Removing The Capacitor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-12

6.18.3 Checking The Capacitor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-12

6.19 VALVE OVERRIDE CONTROLS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-13

6.20 SUCTION MODULATION VALVE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-13

6.20.1 Precheck Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-14

6.20.2 Checking The Stepper valve . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-14

6.21 CONTROLLER AND EXPANSION MODULE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-14

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6.21.1 Handling Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-14

6.21.2 Controller Trouble-Shooting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-15

6.21.3 Controller Programming Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-15

6.21.4 Removing and Installing a Module . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-16

6.22 TEMPERATURE SENSOR SERVICE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-16

6.22.1 Sensor Checkout Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-16

6.22.2 Sensor Replacement . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-17

6.22.3 Sensor Re--Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-18

6.23 MAINTENANCE OF PAINTED SURFACES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-18

6.24 COMPOSITE CONTROL BOX REPAIRS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-18

6.24.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-18

6.24.2 Cracks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-19

6.24.3 Chips And Holes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-19

6.24.4 Inserts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-19

6.24.5 Door Hinge Inserts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-19

6.25 COMMUNICATIONS INTERFACE MODULE INSTALLATION . . . . . . . . . . . . . . . . . . . . . . . . 6-22

ELECTRICAL WIRING SCHEMATIC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

7-1

7.1 INTRODUCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

7-1

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LIST OF ILLUSTRATIONS

FIGURE NUMBER

Page

2-1

2-2

2-3

2-4

2-5

2-10

2-11

3-1

3-2

3-3

3-9

3-11

4-1

4-4

4-5

4-6

4-7

6-1

6-2

6-3

6-4

6-6

6-8

6-9

6-10

6-11

Figure 2-1 Refrigeration Unit -- Front Section . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 2-2 Evaporator Section . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 2-3 Compressor Section . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 2-4 Condenser Section . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 2-5 Control Box Section . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 2-6 Refrigeration Circuit Schematic -- Standard Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 2-7 Refrigeration Circuit Schematic -- Economized Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 2-8 Refrigeration Circuit Schematic -- Unloaded Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 3- 1 Temperature Control System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 3- 2 Key Pad . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 3- 3 Display Module . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 3- 4 Control and Expansion Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 3- 5 Standard Configuration Download Report . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 3- 6 Data Reader . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 4-1 Make Up Air Flow Chart . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 4-2 Controller Operation -- Perishable Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 4-3 Controller Operation -- Frozen Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 4-4 Perishable Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 4-5 Perishable Mode Heating . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 4-6 Frozen Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 4-7 Defrost . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-1 Service Valve . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-2 Suction Service Valve . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-3 Manifold Gauge Set . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-4 R-134a Manifold Gauge/Hose Set . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-5. Refrigeration System Service Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-6. Compressor Service Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-7 Compressor Upper Mounting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-8 Compressor Lower Mounting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-9 High Pressure Switch Testing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-10 Thermostatic Expansion Valve Bulb . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-11 Evaporator Expansion Valve . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-12 Hermetic Thermostatic Expansion Valve Brazing Procedure . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-13 Economizer Expansion Valve . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-14. Unloader Solenoid Valve . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-15. Oil Return Solenoid Valve (ORV), Economizer Solenoid Valve (ESV),

Liquid Injection Solenoid Valve (LIV) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6-11

6-12

6-13

6-15

6-16

6-17

6-18

Figure 6-16. Evaporator Fan Assembly . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-17 Suction Modulation Valve (SMV) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-18 Controller Section of the Control Box . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-19 Sensor Types . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-20 Typical Sensor and Cable Splice . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-21 Supply Sensor Positioning . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

T309

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LIST OF ILLUSTRATIONS

FIGURE NUMBER

Page

6-18

6-19

6-21

6-22

7-1

Figure 6-22 Return Sensor Positioning . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-23 Door Hinge Repair . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-24. Insert Location . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 6-25. Communications Interface Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 7-1 LEGEND . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 7-2 SCHEMATIC DIAGRAM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Figure 7-3 WIRING DIAGRAM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

7-2

7-3

LIST OF TABLES

TABLE NUMBER

Page

2-8

Table 2-1 Safety and Protective Devices . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Table 3-1 Key Pad Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Table 3-2 DataCORDER Configuration Variables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Table 3-3 DataCORDER Standard Configurations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3-2

3-8

Table 3-4 Controller Configuration Variables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-13

Table 3-5 Controller Function Codes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-14

Table 3-6 Controller Alarm Indications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-17

Table 3-7 Controller Pre-Trip Test Codes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-21

Table 3-8 DataCORDER Function Code Assignments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-25

Table 3-9 DataCORDER Pre-Trip Result Records . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-26

Table 3-10 DataCORDER Alarm Indications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-27

Table 6-1 Compressor Kit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

6-6

Table 6-2 Sensor Temperature/Resistance Chart (+/--.002%) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-17

Table 6-3 Crack, Chip & Hole Repair Kit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-20

Table 6-4 Insert Repair Kit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-20

Table 6-5 Drill Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-20

Table 6-6 Recommended Bolt Torque Values . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-22

Table 6-7 R-134a Temperature - Pressure Chart . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-23

vii

T309

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SECTION 1

INTRODUCTION

1.1 INTRODUCTION

1.3.1 Battery

The controller may be fitted with standard replaceable

batteries or a rechargeable battery pack.

The Carrier Transicold model 69NT20--531-300 units

are of lightweight aluminum frame construction,

designed to fit in the front of a container and serve as the

container front wall.

1.3.2 Dehumidification

The unit may be fitted with a humidity sensor. This

sensor allows setting of a humidity set point in the

controller. In the dehumidification mode the controller

will operate to reduce internal container moisture level.

They are one piece, self-contained, all electric units

which are fitted with cooling and heating systems to

provide precise temperature control.

1.3.3 Control Box

The units are supplied with a complete charge of

refrigerant R-134a and compressor lubricating oil and

are ready for operation upon installation. Forklift

pockets are provided for unit installation and removal.

The control box is constructed of composite material

and may be fitted with a lockable door.

1.3.4 Temperature Readout

The base unit operates on nominal 380/460 volt, 3

phase, 50/60 hertz power. An optional autotransformer

may be fitted to allow operation on nominal 190/230 , 3

phase, 50/60 hertz power. Power for the control system

is provided by a transformer which steps the supply

power down to 18 and 24 volts, single phase.

The unit may be fitted with suction and discharge

temperature sensors. The sensor readings may be

viewed on the controller display.

1.3.5 Pres s ure Readout

The unit may be fitted with factory installed suction and

discharge pressure gauges. The unit is fitted with

suction and discharge transducers. The readings may be

viewed on the controller display.

The controller is a Carrier Transicold Micro-Link 2i

microprocessor. The controller will operate

automatically to select cooling, holding or heating as

required to maintain the desired set point temperature

within very close limits.

1.3.6 Interrogator

Units that usetheDataCORDER functionarefittedwith

interrogator receptacles for connection of equipment to

download the recorded data. Two receptacles may be

fitted, one accessible from the front of the unit and the

other mounted inside the container (with the USDA

receptacles).

The controller is fitted with a keypad and display for

viewing or changing operating parameters. The display

is also equipped with lights to indicatevarious modes of

operation.

1.2 CONFIGURATION IDENTIFICATION

1.3.7 Remote Monitoring

Unit identification information is provided on a model

plate located to the left of the economizer. The plate

provides the unit model number and the unit parts

identification number (PID). The model number

identifies the overall unit configuration while the PID

provides information on specific optional equipment,

factory provision to allow for field installation of

optional equipment and differences in detailed parts.

The unit may be fitted with a remote monitoring

receptacle. This item allows connection of remote

indicators for COOL, DEFROST and IN RANGE.

1.3.8 Communications

The unit may be fitted with a communications interface

module. The communications interface module is a

slave module which allows communication with a

master central monitoring station. The module will

respond to communication and return information over

the main power line. Refer to the ship master system

technical manual for further information.

Configuration identification for the models covered

herein are provided in the Carrier Transicold Container

Unit Matrix manual, publication T--300. Printed copies

of the T--300 may be obtained from Carrier Transicold.

Also, aweekly updated copy may befoundat theCarrier

Web site, www.carrier.refrigeration.com.

1.3.9 Compres s or

The unit is fitted with a scroll compressor.

1.3.10 Back Panels

1.3 OPTION DESCRIPTIONS

Various options may be factory or field fitted to the base

unit. Brief descriptions of the options are provided in

the following subparagraphs.

Back panel designs that may be fitted include panels of

aluminum and stainless steel. Panels may be fitted with

access doors and/or hinge mounting.

1-1

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1.3.11 460 Volt Cable

example, additional operating instructions are required

to describe start--up of a unit equipped with an

autotransformer. Where the labels are available with

additional languages, they are listed in the parts list.

Various power cable and plug designs are available for

the main 460 volt supply. The plug options tailor the

cables to each customers requirements.

1.3.17 Plate Set

1.3.12 Cable Res traint

Each unit is equipped with a tethered set of wiring

schematic and wiring diagram plates.

The plate sets are ordered using a seven digit base part

number and a two digit dash number. (See Unit Matrix

Manual, T-300)

Various designs are available for storage of the power

cables. These options are variations of the compressor

section front cover.

1.3.13 Upper Air (Fres h Air Make Up)

The unit may be fitted with an upper fresh air makeup

assembly. These assemblies are supplied in two

designs, the standard design and the micro design. The

openings may also be fitted with screens.

1.3.18 Controller

Replacement controllers may be ordered as a universal

un--configured controller (without configuration

software) or configured.

1.3.14 Evaporator

1.3.19 Stepper Drive

The unit is fitted with an evaporator coil and a hermetic

thermal expansion valve.

All the units covered by this manual have suction

modulating valves which act to control system capacity.

Units indicated as being fitted with “stepper drive”have

digital control motors fitted to the suction modulating

valve to open and close the valve in steps as required.

1.3.15 Evaporator Fan Operation

The units are fitted with Normal Evaporator Fan

Operation, opening of an evaporator fan internal

protector will shut down the unit.

1.3.20 Condens er Grille

1.3.16 Labels

Operating Instruction and Function Code listing labels

will differ depending on the options installed. For

Two styles of condenser grilles are available, direct

bolted grilles and hinged grilles.

T-309

1-2

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SECTION 2

DESCRIPTION

2.1 GENERAL DESCRIPTION

valve, suction modulation valve and evaporator coil

heaters. Theunit model number, serial number and parts

identification number can be found on the serial plate to

the left of the economizer.

2.1.1 Refrigeration Unit -- Front Section

The unit is designed so that the majority of the

components are accessible from the front, see

Figure 2-1. The upper access panels allow entry into the

evaporator section, and the center access panel allows

access to the evaporator expansion valve, unloader

2.1.2 Fres h Air Makeup Vent

The function of the upper or lower makeup air vent is to

provide ventilation for commodities that require fresh

air circulation.

1. Access Panel (Evap. Fan #1)

2. Access Panel (Heaters, Suction Modulating

Valve, Unloader Valve & Evaporator

Expansion Valve)

Parts Identification Number (PID) Plate

9. Power Cables and Plug

10. Condenser Fan

11. Interrogator Connector (Front left)

12. Blank Cover (Temperature Recorder Location)

13. Blank Cover (Lower Fresh Air Makeup Vent

Location)

14. Upper Fresh Air Makeup Vent

15. Access Panel (Evap. Fan #2)

16. Compressor Protection Panel (cutaway view)

3. Fork Lift Pockets

4. Control Box

5. Compressor

6. Receiver or Water Cooled Condenser

7. Economizer

8. Unit Serial Number, Model Number and

Figure 2-1 Refrigeration Unit -- Front Section

T-309

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2.1.3 Evaporator Section

The evaporator fans circulate air through the container

by pulling it in the top of the unit, directing it through

the evaporator coil, where it is heated or cooled, and

discharging it at the bottom.

The evaporator section (Figure 2-2) contains the return

recorder sensor, return temperature sensor, evaporator

expansion valve, unloader valve, suction modulation

valve, dual-speed evaporator fans (EM1 and EM2),

evaporator coil and heater, defrost heaters, defrost

temperature sensor, heat termination thermostat and

suction temperature sensor.

The evaporator components are accessible by removing

the upper rear panel (as shown in the illustration) or by

removing the front access panels.

1. Evaporator Fan Motor #1

2. Return Recorder/Temperature Sensor

3. Humidity Sensor

4. Evaporator Fan Motor #2

5. Defrost Temperature Sensor

6. Heater Termination Thermostat

7. Evaporator Coil

8. Evaporator Coil Heaters

9. Evaporator Expansion Valve Bulb

10. Evaporator Expansion Valve

11. Low Side Access Valve

12. Suction Modulating Valve

13. Suction Temperature Sensor

14. To Compressor

15. From Coil

16. To Coil

17. Unloader Solenoid Valve

Figure 2-2 Evaporator Section

T-309

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2.1.4 Compres s or Section

transducer, discharge temperature sensor and the

suction pressure transducers.

The compressor section includes the compressor (with

high pressure switch) and the oil separator.

The supply temperature sensor, supply recorder sensor

and ambient sensor are located at the left side of the

compressor.

This section also contains the oil return solenoid,

compressor power plug, the discharge pressure

Dis charge

Connection

(Hidden)

Economizer

Connection

Suction

Connection

Oil Return

Connection

1. Compressor Guard

12. Economizer Service Valve

13. Suction Service Valve

2. Supply Temperature/Supply Recorder Sensor

Assembly

14. Discharge Temperature Sensor

15. Oil Return Service Valve

16. Discharge Pressure Transducer

17. Oil Return Solenoid Valve

18. Oil Separator

3. Ambient Sensor

4. Supply Air Thermometer Port (location)

5. Oil Drain

6. Compressor

7. Compressor Sight Glass

19. From Economizer

20. To Condenser

Compressor Power Plug

Discharge Service Valve

21. From Suction Modulating Valve

22. Suction Strainer

10. High Pressure Switch

11. Access Valve

23. Suction Pressure Transducer

Figure 2-3 Compres s or Section

T-309

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2.1.5 Air Cooled Condens er Section

The condenser fan pulls air in the bottom of the coil and

it is discharged horizontally out through the condenser

fan grille.

This section also contains the economizer, economizer

solenoid valve, economizer expansion valve and the

liquid injection solenoid valve.

The air cooled condenser section (Figure 2-4) consists

of the condenser fan, condenser coil, receiver, sight

glass/moisture indicator, liquid line service valve,

filter-drier and fusible plug.

1. Grille and Venturi Assembly

2. Condenser Fan

3. Key

15. From Compressor Discharge

16. Discharge Pressure Transducer

17. Oil Separator

4. Condenser Fan Motor

5. Condenser Coil

18. To Oil Return Solenoid

19. Receiver

6. Condenser Motor Mounting Bracket

7. Condenser Coil Cover

8. Economizer

9. To Evaporator Expansion Valve

10. Liquid Injection Solenoid Valve

11. From Condenser

12. To Condenser

13. To Compressor Economizer Connection

14. To Unloader Solenoid Valve

20. Sight Glass/Moisture Indicator

21. Sight Glass

22. Fusible Plug

23. Access Valve

24. Liquid Line Service Valve

25. Filter-Drier

26. Economizer Expansion Valve

27. Economizer Solenoid Valve

Figure 2-4 Condens er Section

T-309

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2.1.6 Control Box Section

2.1.7 Communications Interface Module

The control box (Figure 2-5) includes the manual

operation switches; circuit breaker (CB-1); compressor,

fan and heater contactors; control power transformer;

fuses; key pad; display module; current sensor module;

controller module expansion module and the

communications interface module.

The communications interface module is a slave

module which allow communication with a master

central monitoring station. The module will respond to

communication and return information over the main

power line. Refer to the master system technical manual

for further information.

18 17

12 11 10 9

1. Compressor Phase A Contactor

2. Compressor Phase B Contactor

3. Heater Contactor

11. Manual Defrost Switch

12. Condenser Fan Switch

13. Controller Battery Pack

4. Display Module

14. Interrogator Connector (Box Location)

15. Control Transformer

5. Communications Interface Module

6. Controller/DataCORDER Module (Controller)

7. Expansion Module

16. Evaporator Fan Contactor - High

17. Evaporator Fan Contactor - Low

18. Condenser Fan Contactor

19. Circuit Breaker -- 460V

8. Key Pad

9. Start-Stop Switch

10. Remote Monitoring Receptacle

20. Current Sensor Module

Figure 2-5 Control Box Section

T-309

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2.2 REFRIGERATION SYSTEM DATA

Model

RSH105

46.5 kg (103 lb)

Mobil ST32

Weight (Dry)

Approved Oil

Oil Charge

a. Compres s or/Motor

As s embly

2957 ml (100 ounces)

The oil level range, with the compressor off,

should be between the bottom and one-eighth

level of the sight glass.

Oil Sight Glass

Verify at --18 _C

(0 _F) container box

temperature

b. Evaporator Expans ion

Valve Superheat

4.4 to 6.7 _C (8 to 12 _F)

c. Economizer Expans ion

Valve Superheat

4.4 to 11.1 _C (8 to 20 _F)

Opens

54 (¦ 3) _C = 130 (¦ 5) _F

38 (¦ 4) _C = 100 (¦ 7) _F

25 (¦ 1.0) kg/cm@ = 350 (¦ 10) psig

18 (¦ 0.7) kg/cm@ = 250 (¦ 10) psig

Charge Requirements -- R-134a

4--Row Coil

d. Heater Termination Thermos tat

e. High Pres s ure Switch

Closes

Cutout

Cut-In

Unit Configuration

Water-Cooled

Condenser

5.33 kg

(11.75 lbs)

f. Refrigerant Charge

4.99kg

(11.0 lbs)

Receiver

Melting point

Torque

99 _C = (210 _F)

6.2 to 6.9 mkg (45 to 50 ft-lbs)

8.9 to 9.7 mkg (65 to 70 ft-lbs)

35 ¦ 5% kg/cm@ = (500 ¦ 5% psig)

6.2 to 6.9 mkg (45 to 50 ft-lbs)

Refer to unit model number plate.

0.5 ¦ 0.2 kg/cm@ (7 ¦ 3 psig)

1.6 ¦ 0.4 kg/cm@ (22 ¦ 5 psig)

g. Fus ible Plug

h. Sight Glas s /Mois ture Indicator

i. Rupture Dis c

Torque

Bursts at

Torque

j. Unit Weight

Cut-In

Cutout

k. Water Pres s ure Switch

T-309

2-6

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2.3 ELECTRICAL DATA

a. Circuit Breaker

CB-1 Trips at

29 amps

62.5 amps

87.5 amps

CB-2 (50 amp) Trips at

CB-2 (70 amp) Trips at

b. Compressor

Motor

Full Load Amps (FLA)

13 amps @ 460 vac

380 vac, Single Phase,

460 vac, Single Phase,

60 hz

50 hz

Full Load Amps

Horsepower

1.3 amps

1.6 amps

0.75 hp

c. Condenser Fan

Motor

0.43 hp

Rotations Per Minute

Voltage and Frequency

Bearing Lubrication

Rotation

1425 rpm

1725 rpm

360 -- 460 vac ¦ 2.5 hz

400 -- 500 vac ¦ 2.5 hz

Factory lubricated, additional grease not required.

Counter-clockwise when viewed from shaft end.

Number of Heaters

Rating

750 watts +5/--10% each @ 230 vac

66.8 to 77.2 ohms @ 20 _C (68 _F)

Sheath

d. Evaporator Coil

Heaters

Resistance (cold)

Type

380 vac/50 hz

460 vac/60 hz

Full Load Amps

High Speed

1.6

2.0

Full Load Amps

Low Speed

0.8

0.70

1.0

0.84

Nominal Horsepower

High Speed

Nominal Horsepower

Low Speed

0.09

0.11

e. Evaporator Fan

Motor(s )

Rotations Per Minute

High Speed

2850 rpm

3450 rpm

Rotations Per Minute

Low Speed

1425 rpm

1750 rpm

Voltage and Frequency

360 -- 460 vac ± 1.25 hz

180 -- 230 vac ± 1.25hz

400 -- 500 vac ± 1.5 hz

200 -- 250 vac ± 1.5 hz

Voltage & Frequency us-

ing power autotransformer

Bearing Lubrication

Rotation

Factory lubricated, additional grease not required

CW when viewed from shaft end

10 amps (F3)

Control Circuit

Controller/DataCORDER

Expansion Module

5 amps (F1 & F2)

f. Fus es

10 amps (F4)

T-309

2-7

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PARAGRAPH 2.3 -- Continued

Orange wire

Power

Output

Red wire

Brown wire

Input voltage

Output voltage

Ground

5 vdc

0 to 3.3 vdc

g. Humidity Sens or

Output voltage readings vers es relative humidity (RH) percentage:

30%

50%

70%

90%

0.99 V

1.65 V

2.31 V

2.97 V

2.4 SAFETY AND PROTECTIVE DEVICES

IP-CP or HPS will shut down the compressor.

Open safety switch contacts on device IP-CM will shut

down the condenser fan motor.

Unit components are protected from damage by safety

and protective devices listed in the following table.

Thesedevices monitortheunit operating conditions and

open a set of electrical contacts when an unsafe

condition occurs.

The entire refrigeration unit will shut down if one of the

following safety devices open: (a) Circuit Breaker(s);

(b)Fuse(F3/15A); or(c) EvaporatorFan MotorInternal

Protector(s) -- (IP-EM).

Open safety switch contacts on either or both of devices

Table 2-1 Safety and Protective Devices

UNSAFE CONDITION

DEVICE

DEVICE SETTING

Circuit Breaker (CB-1) -- Manual Reset

Trips at 29 amps (460 vac)

Trips at 62.5 amps (230 vac)

Trips at 87.5 amps (230 vac)

Excessive current draw

Circuit Breaker (CB-2, 50 amp) --Manual Reset

Circuit Breaker (CB-2, 70 amp) --Manual Reset

Excessive current draw in the

control circuit

Fuse (F3)

10 amp rating

5 amp rating

10 amp rating

N/A

Excessive current draw by the

controller

Fuse (F1 & F2)

Excessive current draw by the

expansion module

Fuse (F4)

Excessive condenser fan mo-

tor winding temperature

Internal Protector (IP-CM) -- Automatic Reset

Internal Protector (IP-CP) -- Automatic Reset

Excessive compressor motor

winding temperature

N/A

Excessive evaporator fan mo-

tor(s) winding temperature

Internal Protector(s) (IP-EM) -- Automatic Reset

Fusible Plug -- Used on the Receiver

N/A

93 _C = (200 _F)

Abnormal pressures/tempera-

tures in the high refrigerant

side

Rupture Disc -- Used on the Water-Cooled Con- 35 kg/cm@ = (500 psig)

denser

Abnormally high discharge

pressure

Opens at 25 kg/cm@

High Pressure Switch (HPS)

(350 psig)

T-309

2-8

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2.5 REFRIGERATION CIRCUIT

2.5.1 Standard Operation

2.5.2 Economized Operation

In the economized mode the frozen rangeand pull down

capacity of theunit is increased by subcooling theliquid

refrigerant entering the evaporator expansion valve.

Overall efficiency is increased because the gas leaving

the economizer enters the compressor at a higher

pressure, therefore requiring less energy to compress it

to the required condensing conditions.

Starting at the compressor, (see Figure 2-6, upper

schematic) the suction gas is compressed to a higher

pressure and temperature.

In thestandard mode, both theeconomizer and unloader

solenoid valves are closed. The gas flows through the

discharge service valve into the oil separator. In the

separator, oil is removed from the refrigerant and stored

forreturn to the compressorwhen theoil return solenoid

valveis opened by thecontroller. Theoil return solenoid

valveis anormally open valvewhich allowsreturn ofoil

during the off cycle.

The refrigerant gas continues into the air-cooled

condenser. When operating with the air-cooled

condenser active, air flowing across the coil fins and

tubes cools the gas to saturation temperature. By

removing latent heat, the gas condenses to a high

pressure/high temperature liquid and flows to the

receiver which stores the additional charge necessary

for low temperature operation.

During economized operation, flow of refrigerant

through the main refrigerant system is identical to the

standard mode. (The unloader solenoid valve is

de--energized [closed] by the controller.)

Liquid refrigerant for use in the economizer circuit is

taken from the main liquid line as it leaves the

filter--drier (see Figure 2-7). The flow is activated when

the controller energizes the economizer solenoid valve.

The liquid refrigerant flows through the economizer

expansion valve and the economizer internal passages

absorbing heat from the liquid refrigerant flowing to the

evaporator expansion valve. The resultant “medium”

temperature/pressure gas enters the compressor at the

economizer service valve.

When operating with the water cooled condenser active

(see Figure 2-6, lower schematic), the refrigerant gas

passes through the air cooled condenser and enters the

water cooled condenser shell. The water flowing inside

the tubing cools the gas to saturation temperature in the

same manner as the air passing over the air cooled

condenser. The refrigerant condenses on the outside of

the tubes and exits as a high temperature liquid. The

water cooled condenser also acts as a receiver, storing

excess refrigerant.

2.5.3 Unloaded Operation

The system will operate in the unloaded mode during

periods of low load, during periods of required

discharge pressure or current limiting, and during

start--up.

The liquid refrigerant continues through the liquid line

service valve, the filter-drier (which keeps refrigerant

clean and dry) and the economizer (which is not active

during standard operation) to the evaporator expansion

valve. As the liquid refrigerant passes through the

variable orifice of the expansion valve, some of it

vaporizes into a gas (flash gas). Heat is absorbed from

the return air by the balance of the liquid, causing it to

vaporize in the evaporator coil. The vapor then flows

through the suction modulation valve to the

compressor.

During unloaded operation, flow of refrigerant through

the main refrigerant system is identical to the standard

mode. (The economizer solenoid valve is de--energized

[closed] by the controller.)

In the unloaded mode, a portion of the mid--stage

compressed gas is bypassed to decrease compressor

capacity. The flow is activated when the controller

opens the unloader solenoid valve (see Figure 2-7.

Opening of the valve creates a bypass from the

economizerservicevalve through the unloadersolenoid

valve and into the suction line on the outlet side of the

suction pressure modulation valve.

The evaporator expansion valve is activated by the bulb

strapped to the suction line near the evaporator outlet.

The valve maintains a constant superheat at the coil

outlet regardless of load conditions.

On systems fitted with a water pressure switch, the

condenser fan will be off when there is sufficient

pressure to open the switch. If water pressure drops

below the switch cut out setting, the condenser fan will

be automatically started. When operating a system

fitted with a condenser fan switch, the condenser fan

will be off when the switch is placed in the “O” position.

The condenser fan will be on when the switch is placed

in the “I” position.

As load on thesystem decreases, thesuctionmodulating

valve decreases flow of refrigerant to the compressor.

This action balances the compressor capacity with the

load and prevents operation with low coil temperatures.

In this mode of operation, the liquid injection solenoid

valve will open as required to provide sufficient liquid

refrigerant flow into the suction line for cooling of the

compressor motor.

T-309

2-9

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STANDARD OPERATION WITH RECEIVER

EVAPORATOR

LOW SIDE ACCESS VALVE

TXV BULB

TXV

SMV

CONDENSER

USV

LIV

STS

ECONOMIZER TXV BULB

ECONOMIZER

FILTER

DRIER

DISCHARGE

SERVICE

CONNECTION

DPT

CPDS

ESV

HPS

OIL SEPARATOR

ECONOMIZER

SERVICE

CONNECTION

RECEIVER

ECONOMIZER

TXV

ORV

FUSIBLE PLUG

SUCTION SERVICE

CONNECTION

SIGHT GLASS

MOISTURE INDICATOR

OIL RETURN

SERVICE VALVE

SPT

LIQUID LINE

SERVICE

CONNECTION

COMPRESSOR

DISCHARGE

LIQUID

SUCTION

STANDARD OPERATION WITH WATER COOLED CONDENSER

EVAPORATOR

LOW SIDE ACCESS VALVE

TXV BULB

TXV

SMV

CONDENSER

USV

LIV

CPSS

QUENCH

TXV

BULB

ECONOMIZER TXV BULB

ECONOMIZER

FILTER

DRIER

DISCHARGE

SERVICE

CONNECTION

DPT

CPDS

RUPTURE DISC

ESV

HPS

ECONOMIZER

SERVICE

CONNECTION

ECONOMIZER

TXV

ORV

SIGHTGLASS/

MOISTURE INDICATOR

SUCTION SERVICE

CONNECTION

OIL RETURN

SERVICE VALVE

SPT

WATER COOLED

CONDENSER

LIQUID LINE

SERVICE

CONNECTION

COMPRESSOR

Figure 2-6 Refrigeration Circuit Schematic -- Standard Operation

T-309

2-10

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EVAPORATOR

LOW SIDE ACCESS VALVE

TXV BULB

TXV

SMV

CONDENSER

LIV

ECONOMIZER TXV BULB

ECONOMIZER

ESV

OIL SEPARATOR

ECONOMIZER

SERVICE

ECONOMIZER

TXV

CONNECTION

RECEIVER

LIQUID LINE

SERVICE CONNECTION

LIQUID

ECONOMIZER PRESSURE

Figure 2-7 Refrigeration Circuit Schematic -- Economized Operation

SMV

TXV BULB

TXV

USV

LIV

ECONOMIZER TXV BULB

OIL SEPARATOR

SUCTION SERVICE

CONNECTION

RECEIVER

LIQUID

ECONOMIZER PRESSURE

SUCTION

Figure 2-8 Refrigeration Circuit Schematic -- Unloaded Operation

T-309

2-11

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SECTION 3

MICROPROCESSOR

3.1 TEMPERATURE CONTROL MICROPRO-

record unit operating parameters and cargo temperature

parameters for future retrieval. Coverage of the

temperaturecontrol softwarebegins with paragraph3.2.

Coverage of the DataCORDER software is provided in

paragraph 3.6.

CESSOR SYSTEM

The temperature control Micro-Link 2i microprocessor

system (see Figure 3- 1) consists of a key pad, display

module, the control module & expansion module set

(controller) and interconnecting wiring. The controller

houses the temperature control software and the

DataCORDER Software. The temperature control

software functions to operate the unit components as

required to provide the desired cargo temperature and

humidity. The DataCORDER software functions to

The key pad and display module serve to provide user

access and readouts for both of the controller functions,

temperature control and DataCORDER. The functions

are accessed by key pad selections and viewed on the

display module. Thecomponents aredesigned to permit

ease of installation and removal.

CONTROL MODULE

EXPANSION MODULE

DISPLAY MODULE

KEY PAD

TEMPERATURE CONTROL SOFTWARE

CONFIGURATION OPERATIONAL

ALARMS

(AL<70)

PRE--TRIP

INTERROGATION

CONNECTOR

SOFTWARE

CONFIGURATION

VARIABLE

FUNCTION

CODE (Cd)

DISPLAY

(CnF##)

DATAREADER

DataCORDER SOFTWARE

CONFIGURATION OPERATIONAL

ALARMS

(AL>69)

DATA

STORAGE

MEMORY

SOFTWARE

Computer Device

With DataLine

Software

CONFIGURATION

VARIABLE

(dCF## read only)

FUNCTION

CODE (dC)

DISPLAY

(Scrollback)

Figure 3- 1 Temperature Control Sys tem

T-309

3-1

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3.1.1 Key Pad

Table 3-1 Key Pad Function

FUNCTION

KEY

The key pad (Figure 3- 2) is mounted on the right-hand

side of the control box. The key pad consists of eleven

push button switches that act as the user’s interface with

the controller. Descriptions of the switch functions are

provided in Table 3-1.

Code Select Accesses function codes.

Displays the pre-trip selection menu. Dis-

continues pre-trip in progress.

Pre-Trip

Displays alarm list and clears the alarm

queue.

Alarm List

Defrost

Interval

Displays selected defrost interval.

PRE

TRIP

CODE

SELECT

Confirms a selection or saves a selection

to the controller.

Enter

DEFROST

INTERVAL

ALARM

LIST

Change or scroll a selection upward Pre-

trip advance or test interruption.

Arrow Up

Arrow

Down

Change or scroll a selection downward.

Pre-trip repeat backward.

Return/

Supply

Displays non-controlling probe tempera-

ture (momentary display).

ENTER

Displays alternate English/Metric scale

(momentary display). When set to _F,

pressure is displayed in psig and vacuum

in “/hg. “P” appears after the value to in-

dicate psig and “i” appears for inches of

mercury.

_C/_F

RETURN

SUPPLY

When set to _C. pressure readings are in

bars. “b” appears after the value to indi-

cate bars.

ALT.

MODE

BATTERY

POWER

Initiate battery backup mode to allow set

point and function code selection if AC

power is not connected.

Battery

Power

This key is pressed to switch the functions

from the temperature software to the Da-

taCORDER Software. The remaining keys

function the same as described above ex-

cept the readings or changes are made to

the DataCORDER programming..

Figure 3- 2 Key Pad

ALT Mode

COOL

HEAT DEFROST IN RANGE ALARM SUPPLY RETURN

NOTE

SETPOINT/Code

AIR TEMPERATURE/Data

The controlling probe in the perishable range

will be the SUPPLY air probe and the control-

ling probe in the frozen range will be the

RETURN air probe.

Figure 3- 3 Dis play Module

5. Supply -- Yellow LED: Energized when the supply air

probe is used for control. When this LED is illumi-

nated, the temperature displayed in the AIR TEMPER-

ATURE display is the reading at the supply air probe.

This LED will flash if dehumidification or humidifi-

cation is enabled.

3.1.2 Dis play Module

The display module (Figure 3- 3) consists of two

backlighted five digit LCD displays and seven indicator

lights. The indicator lights include:

1. Cool -- White LED: Energized when the refrigerant

compressor is energized.

6. Return -- Yellow LED: Energized when the return air

probe is used for control. When this LED is illumi-

nated, the temperature displayed in the AIR TEM-

PERATURE display is the reading at the return air pro-

be. This LED will flash if dehumidification or

humidification is enabled.

2. Heat -- Orange LED: Energized to indicate heater op-

eration in the heat or defrost mode.

3. Defrost -- OrangeLED: Energized when theunit is in

the defrost mode.

4. In-Range -- Green LED: Energized when the con-

trolled temperature probe is within specified toler-

ance of set point.

7. Alarm -- Red LED: Energized when there is an active

or an inactive shutdown alarm in the alarm queue

T-309

3-2

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1. Mounting Screw

6. Control Circuit Power Connection

(Location: In back of controller)

7. Software Programming Port

8. Battery Pack

2. Micro-Link 2i Control/DataCORDER Module

3. Connectors

4. Test Points

5. Fuses

9. Expansion Module

Figure 3- 4 Control and Expans ion Modules

3.1.3 Controller

c. Provide ability to read and (if applicable) modify the

Configuration Software Variables, Operating Soft-

ware Function Codes and Alarm Code Indications.

CAUTION

Do not remove wire harnesses from control-

ler modules unless you are grounded to the

unit frame with a static safe wrist strap.

d. ProvideaPre-Trip step-by-step checkout ofrefrigera-

tion unit performance including: proper component

operation, electronic and refrigeration control opera-

tion, heater operation, probe calibration, pressure

limiting and current limiting settings.

CAUTION

Unplug all controller module wire harness

connectors before performing arc welding

on any part of the container.

e. Provide battery powered ability to access or change

selected codes and set point without AC power con-

nected

NOTE

Do not attempt to service the controller mod-

ules. Breaking the seal will void the warranty.

f. Provide the ability to reprogram the software through

the use of a memory card. The memory card automat-

ically downloads newsoftware to the controllerwhen

inserted.

The Micro--Link 2i controller is a dual module

microprocessor as shown in Figure 3- 4. It is fitted with

test points, harness connectors and a software card

programming port.

3.2.1 Configuration Software (Configuration Vari-

ables )

3.2 CONTROLLER SOFTWARE

The controller software is a custom designed program

that is subdivided into the Configuration Software and

the Operational Software. The controller software

performs the following functions:

The Configuration Software is a variable listing of the

components available for use by the Operational

Software. This software is factory installed in

accordance with the equipment fitted and options listed

on the original purchase order. Changes to the

Configuration Software are required only when a new

controller hase been installed or a physical change has

been made to the unit such as the addition or removal of

an option. A Configuration Variable list is provided in

Table 3-4. Change to the factory installed

Configuration Software is achieved via a configuration

card or communications.

a. Control supply or return air temperature to required

limits, provide modulated refrigeration operation,

economized operation, unloaded operation, electric

heat control and defrost. Defrost is performed to clear

build up of frost and ice and ensure proper air flow

across the coil.

b. Provide default independent readouts of set point and

supply or return air temperatures.

T-309

3-3

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3.2.2 Operational Software (Function codes )

3.3.2 Defros t Interval

Function code Cd27 may be operator set to initiate

defrost at intervals of 3, 6, 9, 12 or 24 hours. It may also

be set to OFF (no defrost). The factory default is 12

hours. (Refer to Table 3-5).

The Operational Software is the actual operation

programming of the controller which activates or

deactivates components in accordance with current unit

operating conditions and operator selected modes of

operation.

3.3.3 Failure Action

Function code Cd29 may be operator set to allow

continued operation in the event the control sensors are

reading out of range. The factory default is full system

shutdown. (Refer to Table 3-5).

The programming is divided into function Codes. Some

of the codes are read only while the remaining codes

may be user configured. The value of the user

configurable codes can be assigned in accordance with

user desired mode of operation. A list of the function

codes is provided in Table 3-5.

3.3.4 Generator Protection

Function codes Cd31(Stagger Start, Offset Time) and

Cd32 (Current Limit) may be operator set to control

start up sequenceofmultiple units and operating current

draw. The factory default allows on demand starting (no

delay) of units and normal current draw. Refer to

Table 3-5.

To access the function codes, perform the following:

a. Press the CODE SELECT key, then press an arrow

key until the left window displays the desired code

number.

3.3.5 Compres s or High Temperature, Low Pres -

s ure Protection.

The controller monitors compressor suction and

discharge temperatures and pressures. If the discharge

temperature exceeds a certain limit, the liquid injection

valve is opened to provide sufficient liquid refrigerant

flow into the economizer line to reduce the discharge

temperature. If the liquid injection is unable to reduce

the discharge temperature sufficiently and the

temperature exceeds the allowed limit, the compressor

will cycle off on a 3 minute timer. The compressor will

also cycle off in a similar manner if the suction pressure

falls belowtheallowed limit. Condenser and evaporator

fans continue to operate during the compressor off

cycle.

b. The right window will display the value of this item

for five seconds before returning to the normal dis-

play mode.

c. If a longer time is desired, press the ENTER key to

extend the time to 30 seconds.

3.3 MODES OF OPERATION

The Operational Software responds to various inputs.

These inputs come from the temperature and pressure

sensors, the temperature set point, the settings of the the

configuration variables and the function code

assignments. The action taken by the Operational

Software will change if any one of the inputs changes.

Overall interaction of the inputs is described as a

“mode” of operation. The modes of operation include,

perishable (chill) mode and frozen mode. Descriptions

of the controller interaction and modes of operation are

provided in the following sub paragraphs.

3.3.6 Peris hable Mode -- Conventional

The unit is capable of maintaining supply air

temperature to within ¦ 0.25_C (¦ 0.5_F) of set point.

Supply air temperature is controlled by positioning of

the suction modulation valve (SMV), cycling of the

compressor and cycling of the heaters.

When cooling from a temperature that is more than

2.5_C (4.5_F) above set point, the system will be in the

perishable pull down mode. It will be in economized

operation with a target SMV position of 100% open.

However, pressure and current limit functions may

restrict the valve, if either exceeds the preset value.

3.3.1 Temperature Control -- Peris hable Mode

Once set point is reached, the unit will transition to the

perishable steady state mode. This results in unloaded

operation with some restriction of the SMV. The SMV

will continue to close and restrict refrigerant flow until

the capacity of the unit and the load are balanced.

If the SMV is at minimum modulation, the controller

has determined that cooling is not required, or the

controllerlogicdetermines suction pressureis at thelow

pressure limit, the unit will transition to the perishable

idle mode. The compressor is turned off and the

evaporator fans continue to run to circulate air

throughout the container. If temperature rises above set

point +0.2_C, the unit will transition back to the

perishable steady state mode

With configuration variable CnF26 (Heat Lockout

Temperature) set to --10_C the perishable mode of

operation is active with set points at or above --10_C

(+14_F). With the variable set to --5_C, the perishable

mode is active at or above --5_C (+23_F). Refer to

Table 3-4.

When in the perishable mode the controller maintains

the supply air temperature at set point, the SUPPLY

indicatorlight will beilluminated onthedisplaymodule

and the default reading on the display window will be

the supply temperature sensor reading.

When the supply air temperature enters the in-range

temperature tolerance (as selected at function code

Cd30), the in-range light will energize.

If the temperature drops to 0.5_C (0.9_F) below set

point, the unit will transition to the perishable heating

T-309

3-4

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mode and the heaters will be energized . The unit will

transition back to the perishable idle mode when the

temperature rises to 0.2_C (0.4_F) below the set point

and the heaters will de-energize

causes the controller to open the suction modulating

valve to match the increased heat load while still

holding the supply air temperature very close to the set

point.

Opening the modulating valve reduces the temperature

of the evaporator coil surface, which increases the rate at

which water is condensed from the passing air.

Removing water from the air reduces the relative

humidity. When the relative humidity sensed is 2%

below the set point , the controller de-energizes the heat

relay. The controller will continue to cycle heating to

maintain relative humidity below the selected set point.

If the mode is terminated by a condition other than the

humidity sensor, e.g., an out-of-range or compressor

shutdown condition, the heat relay is de-energized

immediately.

3.3.7 Peris hable Mode -- Economy

The economy mode is an extension of the conventional

mode. The mode is activated when the setting of

function code Cd34 is “ON”. Economy mode is

provided for power saving purposes. Economy mode

could be utilized in the transportation of temperature

tolerant cargo or non-respiration items which do not

require high airflow for removing respiration heat.

There is no active display indicator that economy mode

has been activated. To check for economy mode,

perform a manual display of code Cd34.

In order to achieve economy mode, a perishable set

point must be selected prior to activation. When

economy mode is active, the evaporator fans will be

controlled as follows:

Two timers are activated in the dehumidification mode

to prevent rapid cycling and consequent contactor wear.

They are:

1. Heater debounce timer (three minutes).

2. Out-of-range timer (five minutes).

The heater debounce timer is started whenever the

heater contactor status is changed. The heat contactor

remains energized (or de-energized) for at least three

minutes even if the set point criteria are satisfied.

The out-of-range timer is started to maintain heater

operation during a temporary out-of-range condition. If

the supply air temperature remains outside of the user

selected in-range setting for more than five minutes, the

heaters will be de-energized to allow the system to

recover. The out-of-range timer starts as soon as the

temperature exceeds the in-range tolerance value set by

function code Cd30.

At the start of each cooling or heating cycle, the

evaporator fans will be run in high speed for three

minutes. They will then be switched to low speed any

time the supply air temperature is within ¦ 0.25_C

(0.45_F)oftheset point and thereturn air temperatureis

less than or equal to the supply air temperature + 3_C

(5.4_F). The fans will continue to run in low speed for

one hour. At the end of the hour, theevaporator fans will

switch back to high speed and the cycle will be repeated.

If bulb mode is active, the economy fan activity will be

overwritten.

3.3.8 Peris hable Mode -- Dehumidification

The dehumidification mode is provided to reduce the

humidity levels inside the container. The mode is

activated when a humidity value is set at at function

code Cd33. The display module SUPPLY led will flash

ON and OFF every second to indicate that the

dehumidification mode is active. Once the Mode is

active and the following conditions are satisfied, the

controller will activate the heat relay to begin

dehumidification.

3.3.9 Peris hable, Dehumidification -- Bulb Mode

Bulb mode is an extension of the dehumidification

mode which allows changes to the evaporator fan speed

and/or defrost termination set points.

Bulb mode is active when configuration code Cd35 is

set to “Bulb”. Once the bulb mode is activated, the user

may then change thedehumidification modeevaporator

fan operation from the default (speed alternates from

low to high each hour) to constant low or constant high

speed. This is done by toggling function code Cd36

from its default of“alt”to “Lo”or“Hi”as desired. Iflow

speed evaporator fan operation is selected, this gives the

user the additional capability of selecting

dehumidification set points from 60 to 95% (instead of

the normal 65 to 95%).

1. The humidity sensor reading is above the set point.

2. The unit is in the perishable steady state mode and

supply air temperature is less than 0.25_C above set

point.

3. The heater debouncetimer (threeminutes) has timed

out.

4. Heater termination thermostat (HTT) is closed.

In addition, if bulb mode is active, function code Cd37

may be set to override the previous defrost termination

thermostat settings. (Refer to paragraph 4.9.5.) The

temperature at which the defrost termination thermostat

will be considered “open” may be changed [in 0.1_C

(0.2_F) increments] to any value between 25.6_C

(78_F)and 4_C (39.2_F) . The temperatureat which the

defrost termination thermostat is considered closed for

interval timer start or demand defrost is 10_C for

“open” values from 25.6_C (78_F) down to a 10_C

setting. For “open” values lower than 10_C, the

“closed” values will decrease to the same value as the

“open” setting. Bulb mode is terminated when:

If the above conditions are true the evaporator fans will

switch from high to low speed operation. The

evaporatorfan speed will switch everyhourthereafteras

long as all conditions are met (see Bulb Mode section

for different evaporator fan speed options). If any

condition except for item (1) becomes false OR if the

relative humidity sensed is 2% below the

dehumidification set point, the high speed evaporator

fans will be energized.

In the dehumidification mode power is applied to the

defrost and drain pan heaters. This added heat load

T-309

3-5

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1. Bulb mode code Cd35 is set to “Nor.”

to “ON”. When economy mode frozen is active, the

system will perform normal frozen mode operations

except that the entire refrigeration system, excluding

the controller, will be turned off when the control

temperature is less than or equal to the set point -- 2_C.

After an off-cycle period of 60 minutes, the unit will

turn on high speed evaporator fans for three minutes,

and then check the control temperature. If the control

temperature is greater than or equal to the set point +

0.2_C., the unit will restart the refrigeration system and

continue to cool until the previously mentioned

off-cycle temperature criteria are met. If the control

temperature is less than the set point + 0.2_C, the unit

will turn off the evaporator fans and restart another 60

minute off-cycle.

2. Dehumidification code Cd33 is set to “Off.”

3. The user changes the set point to one

that is in the frozen range.

When bulb mode is disabled by any of the above, the

evaporator fan operation for dehumidification reverts to

“alt” and the DTS termination setting resets to the value

determined by controllerconfiguration variableCnF41.

3.3.10 Temperature Control -- Frozen Mode

With configuration variable CnF26 (Heat Lockout

Temperature) set to --10_C the frozen mode ofoperation

is active with set points at or below --10_C (+14_F).

With the variable set to --5_C, the frozen mode is active

at or below --5_C (+23_F).

3.4 CONTROLLER ALARMS

When in the frozen mode the controller maintains the

return air temperature at set point, the RETURN

indicatorlight will beilluminated onthedisplaymodule

and the default reading on the display window will be

the return air probe reading.

Alarm display is an independent controller software

function. If an operating parameter is outside of

expected range or a components does not return the

correct signals back to the controller an alarm is

generated. A listing of the alarms is provided in

Table 3-6.

When the return air temperature enters the in-range

temperature tolerance as selected at function code

Cd30, the in-range light will energize.

The alarm philosophy balances the protection of the

refrigeration unit and that of the refrigerated cargo. The

action taken when an error is detected always considers

the survival of the cargo. Rechecks are made to confirm

that an error actually exists.

3.3.11 Frozen Mode -- Conventional

Frozen range cargos are not sensitive to minor

temperature changes. The method of temperature

control employed in this range takes advantage of this

fact to greatly improve the energy efficiency of the unit.

Temperature control in the frozen range isaccomplished

by cycling thecompressoron and offas theload demand

requires.

Some alarms requiring compressor shutdown havetime

delays before and after to try to keep the compressor on

line. An example is alarm code “LO”, (low main

voltage), when a voltage drop of over 25% occurs, an

indication is given on the display, but the unit will

continue to run.

When cooling from a temperature that is more than

2.5_C (4.5_F) above set point, the system will be in the

frozen pull down mode. It will transition to economized

operation with a target SMV position of 100% open.

However, pressure and current limit functions may

restrict the valve, if either exceeds the preset value.

When an Alarm Occurs:

a. The red alarm light will illuminate for alarm code

numbers 13, 17, 20, 21, 22, 23, 24, 25, 26, and 27.

b. If a detectable problem is found to exist, its alarm

code will be alternately displayed with the set point

on the left display.

Once set point is reached, the unit will transition to the

frozen steady state mode. (Economized operation with

maximum allowed suction modulating valve opening.)

c. The user should scroll through the alarm list to deter-

mine what alarms exist or have existed. Alarms must

be diagnosed and corrected before the Alarm List can

be cleared.

When temperature drops to set point minus 0.2_C and

the compressor has run for at least five minutes, the unit

will transition to the frozen idle mode. The compressor

is turned off and the evaporator fans continue to run to

circulate air throughout the container. If temperature

rises above set point +0.2_C, the unit will transition

back to the frozen steady state mode.

To Display Alarm Codes :

a. While in the Default Display mode, press the

ALARM LIST key. This accesses the Alarm List Dis-

play Mode, which displays any alarms archived in the

Alarm Queue.

If the temperature drops 10_C below set point, the unit

will transition to the frozen “heating” mode. In the

frozen heating mode the evaporator fans are brought to

high speed. The unit will transition back to the frozen

steady statemodewhen thetemperaturerises back tothe

transition point.

b. The alarm queue stores up to 16 alarms in the se-

quence in which they occurred. The user may scroll

through the list by depressing an ARROW key.

c. The left display will show “AL##,” where ## is the

alarm number sequentially in the queue.

3.3.12 Frozen Mode -- Economy

d. The right display will show the actual alarm code.

“AA##” will display for an active alarm, where “##”

is the alarm code. Or “IA##” will display for an inac-

tive alarm. See Table 3-6.

In order to activate economy frozen mode operation, a

frozen set point temperature must be selected. The

economy mode is active when function codeCd34 is set

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e. “END” is displayed to indicate the end of the alarm

list if any alarms are active.

The DataCORDER performs the following functions:

a. Logs data at 15, 30, 60 or 120 minute intervals and

stores two years’ of data (based on one hour interval).

f. “CLEAr” is displayed if all alarms are inactive. The

alarm queue may than be cleared by pressing the EN-

TER key. The alarm list will clear and “-- -- -- -- -- ”

will be displayed.

b. Records and displays alarms on the display module.

c. Records results of pre--trip testing.

d. Records DataCORDER and temperature controlsoft-

ware generated data and events as follows:

3.5. UNIT PRE-TRIP DIAGNOSTICS

Pre--Trip Diagnostics is an independent controller

function which will suspend normal refrigeration

controller activities and provide preprogrammed test

routines. The test routines include Auto Mode testing,

which automatically preforms a pre programmed

sequenced of tests, or Manual Mode testing, which

allows the operator to select and run any of the

individual tests.

Container ID Change

Software Upgrades

Alarm Activity

Battery Low (Battery Pack)

Data Retrieval

Defrost Start and End

Dehumidification Start and End

Power Loss (w/wo battery pack)

Power Up (w/wo battery pack)

Remote Probe Temperatures in the Container

(USDA Cold treatment and Cargo probe recording)

Return Air Temperature

Set Point Change

Supply Air Temperature

CAUTION

Pre-trip inspection should not be performed

with critical temperature cargoes in the con-

tainer.

CAUTION

When Pre-Trip key is pressed, economy, de-

humidification and bulb mode will be deac-

tivated. At the completion of Pre-Trip activi-

ty, economy, dehumidification and bulb

mode must be reactivated.

Real Time Clock Battery (Internal Battery) Replace-

ment

Real Time Clock Modification

Trip Start

ISO Trip Header (When entered via Interrogation

program)

Testing may be initiated by use of the Key Pad or via

communication, but when initiated by communication

the controller will execute the entire battery of tests

(auto mode).

At the end of a pre-trip test, the message “P,” “rSLts”

(pretest results) will be displayed. Pressing the ENTER

key will allow the user to see the results for all subtests.

The results will be displayed as “PASS” or “FAIL” for

all the tests run to completion.

Economy Mode Start and End

“Auto 2” Pre-Trip Start and End

Bulb Mode Start

Bulb Mode changes

Bulb Mode End

A detailed description of the pre-trip tests and test codes

is provided in Table 3-7. detailed operating instructions

are provided in paragraph 4.7.

USDA Trip Comment

Humidification Start and End

USDA Probe Calibration

3.6.2 DataCORDER Software

3.6 DataCORDER

3.6.1 Des cription

The DataCORDER Software is subdivided into the

Configuration Software, Operational Software and the

Data Memory.

The Carrier Transicold “DataCORDER,” software is

integrated into the controller and serves to eliminate the

temperature recorder and paper chart. The

DataCORDER functions may be accessed by key pad

selections and viewed on thedisplay module. Theunitis

also fitted with interrogation connections (see

Figure 3- 1) which may be used with the Carrier

Transicold Data Reader to down load data. A personal

computer with Carrier Transicold Data View software

may also be used to download data and configure

settings. The DataCORDER consists of:

a. Operational Software

The Operational Software reads and interprets inputs

for use by the Configuration Software. The inputs are

labeled Function Codes. There are 35 functions (see

Table 3-8) which the operator may access to examine

the current input data or stored data. To access these

codes, do the following:

1 Press the ALT. MODE & CODE SELECT keys.

Configuration Software

Operational Software

Data Storage Memory

Real Time Clock (with internal battery backup)

Six thermistor inputs

2 Press an arrow key until the left window displays the

desired code number. The right window will display

the value of this item for five seconds before return-

ing to the normal display mode.

Interrogation Connections

Power supply (battery pack).

3 If a longer time is desired, press the ENTER key to

extend the time to 30 seconds.

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Table 3-2 DataCORDER Configuration Variables

TITLE

CONFIGURATION NO.

DEFAULT

OPTION

-- --

dCF01

(Future Use)

-- --

dCF02

Sensor Configuration

2,5,6,9,54,64,94

15,30,60,120

Low, Normal

A,b,C

dCF03

Logging Interval (Minutes)

Short

dCF04

Thermistor Format

dCF05

Thermistor Sampling Type

dCF06

Controlled Atmosphere/Humidity Sampling Type

Alarm Configuration USDA Sensor 1

Alarm Configuration USDA Sensor 2

Alarm Configuration USDA Sensor 3

Alarm Configuration Cargo Sensor

A,b

dCF07

dCF08

Auto, On, Off

dCF09

dCF10

b. Configuration Software

5. Phase A current

6. Phase B current

7. Phase C current

8. Main voltage

9. Suction modulation valve percentage

10. Discrete outputs (Bit mapped -- require special

handling if used)

11. Discrete inputs (Bit mapped -- require special

handling if used)

12. Ambient sensor

13. Compressor suction sensor

14. Compressor discharge sensor

15. Return temperature sensor

16. Supply temperature sensor

17 Defrost temperature sensor

18. Discharge pressure transducer

19. Suction pressure transducer

20. Condenser pressure transducer

The configuration software controls the recording and

alarm functions of the DataCORDER. Reprogramming

to the factory installed configuration is achieved via the

same configuration card as the unit control module

software. Changes to the unit DataCORDER

configuration may be made made using the Data View

integration device. A listing of the configuration

variables is provided in Table 3-2. Descriptions of

DataCORDER operation for each variable setting are

provided in the following paragraphs.

3.6.3 Sens or Configuration (dCF02)

Two modes of operation may be configured, the

Standard Mode and the Generic Mode.

a. Standard Mode

In the standard mode, the user may configure the

DataCORDER to record data using one of seven

standard configurations. Standard configuration

variables, with descriptions, are listed in Table 3-3.

The six thermistor inputs (supply, return, USDA #1, #2,

#3 and cargo probe) and the humidity sensor input will

be generated by the DataCORDER. An example of a

report using a standard configuration is shown in

Figure 3- 5.

Table 3-3 DataCORDER Standard Configurations

Standard

Des cription

Config.

2 sensors

2 thermistor inputs(supply & return)

(dCF02=2)

5 sensors 2 thermistor inputs(supply & return)

(dCF02=5) 3 USDA thermistor inputs

NOTE

2 thermistor inputs(supply & return)

The DataCORDER software uses the supply

and return recorder sensors (SRS,RRS). The

temperature control software uses the supply

and return temperature sensors (STS,RTS) .

6 sensors

3 USDA thermistor inputs

(dCF02=6)

1 humidity input

9 sensors

Not Applicable

(dCF02=9)

b. Generic Mode

2 thermistor inputs(supply & return)

6 sensors

3 USDA thermistor inputs

(dCF02=54)

The generic recording mode allows user selection of the

network data points to be recorded. The user may select

up to a total of eight data points for recording. A list of

the data points available for recording follows.

Changing the configuration to generic and selecting

which data points to record may be done using the

Carrier Transicold Data Retrieval Program.

1 cargo probe (thermistor input)

2 thermistor inputs(supply & return)

3 USDA thermistor inputs

7 sensors

(dCF02=64) 1 humidity input

1 cargo probe (thermistor input)

2 thermistor inputs(supply & return)

3 USDA thermistor inputs

1. Control mode

2. Control temperature

3. Frequency

10 sensors

(dCF02=94)

1 humidity input

1 cargo probe (thermistor input)

3 C.A. inputs (NOT APPLICABLE)

4. Humidity

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Raw Data Report for ABC1234567

May 31, 2001 to Jun 04, 2001

System Configuration at the Time of Interrogation:

Interrogated On Sept 05, 2001

Extracted by DataLine Rev 1.0.0

Controller Software: 5120

Controller Serial #: 04163552

Bill of Lading #: 1

Origin:

Origin Date:

Destination:

Discharge Date:

Comment: DataLine Tool

Probe Calibration Readings: USDA1: 0.0 USDA2: 0.0 USDA3: 0.0 Cargo: 0.0

Temperature Units: Centigrade

________________________________________________________________________________________

May 31, 2001

Setpoint: 1.66, Container :

Serial : 04189552

9 Sensors Logged at 15 Minute Interval

Sensor

Format

Resolution

Figure 3- 5 Standard Configuration Download Report

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3.6.4 Logging Interval (dCF03)

2. Controller DC battery packpower: If a battery pack

is installed, the DataCORDER will power up for

communication when an interrogation cable is plugged

into an interrogation receptacle.

The user may select four different time intervals

between data recordings. Data is logged at exact

intervals in accordance with the real time clock. The

clock is factory set at Greenwich Mean Time (GMT).

3. External DC battery pack power: A 12 volt battery

pack may also be plugged into the back of the

interrogation cable, which is then plugged into an

interrogation port. No controller battery pack is

required with this method.

3.6.5 Thermistor Format (dCF04)

The user may configure the format in which the

thermistor readings are recorded. The short resolution is

a1 byteformat and thelong resolutionis a2 byteformat.

Theshort requires less memory and records temperature

in 0.25°C (0.45°F)steps when in theperishable modeor

0.5°C (0.9°F) steps when in the frozen mode. The long

records temperature in 0.01°C (0.02°F) steps for the

entire range.

4. Real Time Clock demand: If the DataCORDER is

equipped with a charged battery pack and AC power is

not present, the DataCORDER will power up when the

real time clock indicates that a data recording should

take place. When the DataCORDER is finished

recording, it will power down.

3.6.6 Sampling Type (dCF05 & dCF06)

During DataCORDER power-up, while using

battery-pack power, the controller will perform a

hardware voltage check on the battery. If the hardware

check passes, the Controller will energize and performa

software battery voltage check before DataCORDER

logging. If either test fails, the real time clock battery

power-up will be disabled until the next AC power

cycle. Further DataCORDER temperature logging will

be prohibited until that time.

Three types of data sampling are available, average,

snapshot and USDA. When configured to average, the

average of readings taken every minute over the

recording period is recorded. When configured to

snapshot, the sensor reading at the log intervale time is

recorded. When USDA is configured the supply and

return temperature readings are averaged and the 3

USDA probe readings are snapshot.

3.6.7 Alarm Configuration (dCF07 -- dCF10)

An alarm will be generated when the battery voltage

transitions from good to bad indicating that the battery

pack needs recharging. If the alarm condition persists

for more than 24 hours on continuous AC power, the

battery pack needs replacement.

The USDA and cargo probe alarms may be configured

to OFF, ON or AUTO.

If a probe alarm is configured to OFF, then the alarm for

this probe is always disabled.

3.6.9 Pre-Trip Data Recording

If a probe alarm is configured to ON, then the associated

alarm is always enabled.

The DataCORDER will record the initiation of a

pre-trip test (refer to paragraph 3.5) and the results of

each of the tests included in pre--trip. The data is

time-stamped and may be extracted via the Data

Retrieval program. Refer to Table 3-9 for a description

of the data stored in the DataCORDER for each

corresponding Pre-Trip test.

If the probes are configured to AUTO, they act as a

group. This function is designed to assist users who

keep their DataCORDER configured for USDA

recording, but do not install the probes for every trip. If

all the probes are disconnected, no alarms are activated.

As soon as one of the probes is installed , then all of the

alarms are enabled and theremaining probes that arenot

installed will give active alarm indications.

3.6.10 DataCORDER Communications

The DataCORDER will record the initiation of a

pre-trip test (refer to paragraph 3.5) and the results of

each of the tests included in pre--trip. The data is

time-stamped and may be extracted via the Data

Retrieval program. Refer to Table 3-9 for a description

of the data stored in the DataCORDER for each

corresponding Pre-Trip test.

Data retrieval from the DataCORDER can be

accomplished by using one of the following;

DataReader, DataLine/DataView or a communications

interface module.

a. DataReader

The Carrier Transicold Data Reader (see Figure 3- 6) is

a simple to operate hand held device designed to extract

data from the DataCORDER and then upload it to a

personal computer. The Data Reader has the ability to

store multiple data files. Refer to Data Retrieval manual

62-02575 for a more detailed explanation of the

DataReader

3.6.8 DataCORDER Power-Up

The DataCORDER may be powered up in any one of

four ways:

1. Normal AC power: The DataCORDER is powered

up when the unit is turned on via the stop-start switch.

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Exposing infested fruit to temperatures of 2.2 degrees

Celsius (36_F) or below for specific periods results in

the mortality of the various stages of this group of

insects.

In response to the demand to replace fumigation with

this environmentally sound process, Carrier has

integrated Cold Treatment capability into its

microprocessor system. These units have the ability to

maintain supply air temperature within one-quarter

degree Celsius of setpoint and record minute changes in

product temperature within the DataCORDER

memory, thus meeting USDA criteria. Information on

USDA is provided in the following subparagraphs

DataReader

a. USDA Recording

A special type of recording is used for USDA cold

treatment purposes. Cold treatment recording requires

three remote temperature probes be placed at prescribed

locations in the cargo. Provision is made to connect

these probes to the DataCORDER via receptacles

located at the rear left-hand side of the unit. Four or five

receptacles are provided. The four three-pin receptacles

are for the probes. The five pin receptacle is the rear

connection for the Interrogator. The probe receptacles

are sized to accept plugs with tricam coupling locking

devices. A label on the back panel of the unit shows

which receptacle is used for each probe.

Figure 3- 6 Data Reader

b. DataView

The DataView software for a personal computer is

supplied on a floppy disk. This software allows

interrogation, configuration variable assignment,

screen view of the data, hard copy report generation,

cold treatment probe calibration, cold treatment

initialization and file management. Refer to Data

Retrieval manual 62-02575 for a more detailed

explanation of the DataView interrogation software.

The standard DataCORDER report displays the supply

and return air temperatures. The cold treatment report

displays USDA #1, #2, #3 and the supply and return air

temperatures. Cold treatment recording is backed up by

a battery so recording can continue if AC power is lost.

c. Communications Interface Module

b. USDA/ Mes s age Trip Comment

The communications interface module is a slave

module which allows communication with a master

central monitoring station. The module will respond to

communication and return information over the main

power line.

A special feature is incorporated in DataLine/DataView

which allows the user to enter a USDA (or other)

message in the header of a data report. The maximum

message length is 78 characters. Only one message will

be recorded per day.

With a remote monitoring unit installed, all functions

and selectable features that are accessible atthe unitmay

be performed at the master station. Retrieval of all

DataCORDER reports may also be performed. Refer to

the master system technical manual for further

information.

3.6.12 USDA Cold Treatment Procedure

The following is a summary of the steps required to

initiate a USDA Cold Treatment.

a. Calibrate the three USDA probes by ice bathing the

probes and performing the calibration function with

the DataReader, DataView or DataLine. This calibra-

tion procedure determines the probe offsets and

stores them in the controller for use in generating the

cold treatment report. Refer to the Data Retrieval

manual 62-02575 for more details.

d. DataLine

The DataLINE software for a personal computer is

supplied on both floppy disks and CD. This software

allows

interrogation,

configuration

variable

assignment, screen view of the data, hard copy report

generation, cold treatment probe calibration and file

management. Refer to Data Retrieval manual 62-10629

for a more detailed explanation of the DataLINE

interrogation software. The DataLine manual may be

found on the net at www.contaner.carrier.com

b. Pre-cool the containerto thetreatment temperatureor

below.

c..Install the DataCORDER module battery pack (if not

already installed).

3.6.11 USDA Cold Treatment

Sustained cold temperature has been employed as an

effective postharvest method for the control of

Mediterranean and certain other tropical fruit flies.

d. Place the three probes. The probes are placed into the

pulp ofthe product (at thelocations defined in thefol-

lowing table) as the product is loaded.

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have to be inactive in order to clear the alarm list. To

Clear the Alarm List:

Place in pulp of the product located next

to the return air intake.

Sensor 1

Sensor 2

Place in pulp of the product five feet

from the end of the load for 40 foot con-

tainers, or three feet from the end of the

load for 20 foot containers. This probe

should be placed in a center carton at

one-half the height of the load.

1. Press the ALT. MODE & ALARM LIST keys.

2. Press the UP/DOWN ARROW key until “CLEAr” is

displayed.

Place in pulp of product five feet from

the end of the load for 40 foot containers

or three feet from the end of the load for

20 foot containers. This probe should be

placed in a carton at a side wall at one-

half the height of the load.

3. Press the ENTER key. The alarm list will clear and

“-- -- -- -- -- ” will be displayed.

Sensor 3

4. Press the ALARM LIST key. “AL” will show on the

left display and “-- -- -- -- -- ”on theright display when

there are no alarms in the list.

e. To initiate USDA Recording, connect the personal

computer and perform the configuration as follows,

using either the Data View or Data Line software:

1. Enter ISO header information

2. Enter a trip comment if desired

5. Upon clearing of the Alarm Queue, the Alarm light

will be turned off.

3. Configure the DataCORDER for five probes (s, r,

P1, P2, P3) (dcf02=5)

3.6.14 ISO Trip Header

4. Configure the logging interval for one hour.

5. Set the sensor configuration to “USDA”.

6. Configure for two byte memory storage format

(dcf04=LONG).

7. Perform a “trip start”

3.6.13 DataCORDER Alarms

DataLine provides the user with an interface to

view/modify current settings of the ISO trip header

through the ISO Trip Header screen.

The ISO Trip Header screen is displayed when the user

clicks on the “ISO Trip Header” button in the “Trip

Functions” Group Box on the System Tools screen.

The alarm display is an independent DataCORDER

function. If an operating parameter is outside of the

expected range or a component does not return the

correct values back to the DataCORDER an alarm is

generated. The DataCORDER contains a buffer of up to

eight alarms. A listing of the DataCORDER alarms is

provided in Table 3-10, page 3-27. Refer to paragraph

3.6.7 for configuration information.

F9 function -- Provides the user with a shortcut for

manually triggering the refresh operation.Before

sending modified parameter values, the user must

ensure that a successful connection is established with

the Controller.

If the connection is established with the DataCorder, the

current contents of the ISO Trip Header from the

DataCorder will be displayed in each field. If the

connection is not established with the DataCorder, all

fields on the screen will be displayed as “X’s”.If at any

time during the display of the ISO Trip Header screen

the connection is not established or is lost, the user is

alerted to the status of the connection.

To display alarm codes:

a. While in the Default Display mode, press the ALT.

MODE & ALARM LIST keys. This accesses the Da-

taCORDER Alarm List Display Mode, which dis-

plays any alarms stored in the Alarm Queue.

b. To scroll to the end of the alarm list press the UP AR-

ROW. Depressing the DOWN ARROW key will

scroll the list backward.

c. The left display will show “AL#” where # is the

alarms number in the queue. The right display will

show “AA##,” if the alarm is active, where ## is the

alarm number. “IA##,” will show if the alarm is inac-

tive

After modifying the values and ensuring a successful

connection has been made with the DataCorder, click on

the “Send” button to send the modified parameter

values.

d. “END” is displayed to indicate the end of the alarm

list if any alarms are active. “CLEAr” is displayed if

all the alarms in the list are inactive.

e. If no alarms are active, the Alarm Queue may be

cleared. The exception to this rule is the DataCORD-

ER Alarm Queue Full alarm (AL91) , which does not

The maximum allowed length of the ISO Trip Header is

128 characters.If the user tries to refresh the screen or

close the utility without sending the changes made on

the screen to the DataCorder, the user is alerted with a

message.

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Table 3-4 Controller Configuration Variables

NOTES

1. Configuration numbers not listed are not used in this application. These items may appear when loading

configuration software to the controller but changes will not be recognized by the controller programming.

CONFIGURATION

TITLE

Evaporator Fan Speed

DEFAULT

dS (Dual)

OPTION

SS (Single)

NUMBER

CnF02

CnF04

CnF11

CnF16

CnF22

CnF23

CnF24

CnF25

CnF26

CnF28

CnF31

CnF33

CnF34

CnF37

Dehumidification Mode

OFF

Defrost “Off” Selection

noOFF

On (Yes)

OFF

DataCORDER Present

OFF (No)

Std, Full

SAv

Economy Mode Option

Defrost Interval Timer Save Option

Long Pre Trip Test Sequence Enabled

Pre-Trip Test Points/Results Recording Option

Heat Lockout Change Option

Bulb Mode Option

noSAv

Off

rSLtS

dAtA

Set to --10_C

NOr

Set to --5_C

bULb

Probe Check Option

Std

SPEC

SnAP

Snap Freeze Option

OFF

Degree Celsius Lockout Option

Electronic Temperature Recorder

bOth

rEtUR (Return)

suPPl, BOth

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Table 3-5 Controller Function Codes (Sheet 1 of 3)

DESCRIPTION

Code

No.

TITLE

Note: If the function is not applicable, the dis play will read “-- -- -- -- -- ”

Dis play Only Functions

Displays the SMV percent open. The right display reads 100% when the valve is

fully open. The valve will usually be at 10% on start up of the unit except in very

high ambient temperatures.

Suction Modulation

Valve Opening (%)

Cd01

Cd02 Not Applicable

Not used

The current sensor measures current draw in lines L1 & L2 by all of the high

voltage components. It also measures current draw in compressor motor leg T3.

The compressor leg T3 current is displayed.

Compressor Motor

Current

Cd03

The current sensor measures current on two legs. The third unmeasured leg is cal-

culated based on a current algorithm. The current measured is used for control

and diagnostic purposes. For control processing, the highest of the Phase A and B

current values is used for current limiting purposes. For diagnostic processing,

the current draws are used to monitor component energization.. Whenever a heat-

er or a motor is turned ON or OFF, the current draw increase/reduction for that

activity is measured. The current draw is then tested to determine if it falls within

the expected range of values for the component. Failure of this test will result in a

pre-trip failure or a control alarm indication.

Cd04 Line Current,

Phase A

Cd05 Line Current,

Phase B

Cd06 Line Current,

Phase C

Cd07 Main Power Voltage The main supply voltage is displayed.

Main Power Fre-

quency

The value of the main power frequency is displayed in Hertz. The frequency dis-

Cd08

Cd09

Cd10

Cd11

Cd12

played will be halved if either fuse F1 or F2 is bad (alarm code AL21).

Ambient Tempera-

ture

The ambient sensor reading is displayed.

Compressor Suction

Temperature

Compressor suction temperature sensor reading is displayed.

Compressor discharge temperature sensor reading is displayed.

Compressor Dis-

charge Temperature

Compressor Suction

Pressure

Compressor suction pressure transducer reading is displayed.

Not used

Cd13 Not Applicable

Compressor Dis-

Cd14

Compressor discharge pressure transducer reading is displayed.

charge Pressure

Cd15 Unloader Valve

The status of the valve is displayed (Open - Closed).

Compressor Motor

Cd16

Records total hours of compressor run time. Total hours are recorded in incre-

ments of 10 hours (i.e., 3000 hours is displayed as 300).

Hour Meter

Relative Humidity

Humidity sensor reading is displayed. This code displays the relative humidity, as

a percent value.

Cd17

(%)

Cd18 Software Revision # The software revision number is displayed.

This code checks the Controller/DataCORDER battery pack. While the test is

running, “btest” will flash on the right display, followed by the result. “PASS”

will be displayed for battery voltages greater than 7.0 volts. “FAIL” will be dis-

played for battery voltages between 4.5 and 7.0 volts, and “-- -- -- -- -- ” will be

displayed for battery voltages less than 4.5 volts. After the result is displayed for

four seconds, “btest” will again be displayed, and the user may continue to scroll

through the various codes.

Cd19 Battery Check

This code indicates the dash number of the model for which the Controller is con-

figured (i.e., if the unit is a 69NT40-531-100, the display will show “31100”).

Cd20 Config/Model #

Cd21 Economizer Valve

The status of the valve is displayed (Open - Closed).

T-309

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Table 3-5 Controller Function Codes (Sheet 2 of 3)ff

Cd22 Compressor State

Cd23 Evaporator Fan

The status of the compressor is displayed (Off, On).

Displays the current evaporator fan state (high, low or off).

Controlled

Cd24

Not used in this application

Atmosphere State

Compressor Run

This code displays the time remaining until the unit goes into defrost (in tenths of

an hour). This value is based on the actual accumulated compressor running time.

Time Remaining

Until Defrost

Cd25

Cd26

Defrost Temperature

Sensor Reading

Defrost temperature sensor reading is displayed.

Configurable Functions

NOTE

Function codes Cd27 through Cd37 are user-selectable functions. The operator can change the value of

these functions to meet the operational needs of the container.

The defrost interval is the time between defrost cycles. Five selectable values are

available: 3, 6, 9, 12 or 24 hours. The factory default value is 12 hours. Follow-

ing a start--up or after termination of a defrost, the time will not begin counting

down until the defrost temperature sensor (DTS) reading falls below set point. If

the reading of DTS rises above set point any time during the timer count down,

the interval is reset and the countdown begins over. If DTS fails, alarm code

AL60 is activated and control switches over to the the return temperature sensor.

The controller will act in the same manner as with the DTS except the return tem-

Defrost Interval

(Hours)

perature sensor reading will be used.

Cd27

Defrost Interval Timer Value (Configuration variable CnF23): If the software is

configured to “SAv” (save) for this option, then the value of the defrost interval

timer will be saved at power down and restored at power up. This option prevents

short power interruptions from resetting an almost expired defrost interval, and

possibly delaying a needed defrost cycle.

NOTE

The defrost interval timer counts only during compressor run time.

This code determines the temperature units (_C or _F) which will be used for all

temperature displays. The user selects _C or _F by selecting function code Cd28

and pushing the ENTER key. The factory default value is Celsius units.

Temperature Units

(_C or _F)

Cd28

NOTE

This function code will display “--- --- --- --- --- “ if Configuration Variable

CnF34 is set to _F.

If all of the control sensors are out of range (alarm code AL26) or there is a probe

circuit calibration failure (alarm code AL27), the unit will enter the shutdown

state defined by this setting. The user selects one of four possible actions as fol-

lows:

A -- Full Cooling (compressor is on, economized operation. SMVsubject to pressure

Failure Action

(Mode)

and current limit.)

Cd29

B -- Partial Cooling (Compressor is on, standard operation. SMV subject to pressure

and current limit.)

C -- Evaporator Fan Only (Compressor is off, evaporator fans on high speed, not ap-

plicable with frozen set points.

D -- Full System Shutdown -- Factory Default (shut down every component in the

unit)

The in-range tolerance will determine the band of temperatures around the set

point which will be designated as in-range. If the control temperature is in-range,

the in-range light will be illuminated. There are four possible values:

1 = ¦ 0.5_C (¦ 0.9_F)

Cd30 In-Range Tolerance

2 = ¦ 1.0_C (¦ 1.8_F)

3 = ¦ 1.5_C (¦ 2.7_F)

4 = ¦ 2.0_C (¦ 3.6_F) -- Factory Default

T-309

3-15

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Table 3-5 Controller Function Codes (Sheet 3 of 3)

The stagger start offset time is the amount of time that the unit will delay at start-

up, thus allowing multiple units to stagger their control initiation when all units

are powered up together. The eight possible offset values are:

Stagger Start Offset

Time (Seconds)

Cd31

Cd32

0 (Factory Default), 3, 6, 9, 12, 15, 18 or 21 seconds

The current limit is the maximum current draw allowed on any phase at any time.

Limiting the unit’s current reduces the load on the main power supply. This is

accomplished by reducing the SMV position until current draw is reduced to the

set point. When desirable, the limit can be lowered. Note, however, that capacity

is also reduced. The five values for 460vac operation are: 15, 17, 19, 21 (Factory

Default), 23

Current Limit

(Amperes)

Relative humidity set point is available only on units configured for dehumidifi-

cation. When the mode is activated, the control probe LED flashes on and off ev-

ery second to alert the user. If not configured, the mode is permanently deacti-

vated and “-- -- -- -- -- ” will display. The value can be set to “OFF.” “TEST,” or a

range of 65 to 95% relative humidity in increments of 1%. [If bulb mode is active

(code Cd35) and “Lo” speed evaporator motors are selected (code Cd36) then set

point ranges from 60 to 95%.] When “TEST” is selected or test set point is

entered, the heat LED should illuminate, indicating that dehumidification mode is

activated. After a period of five minutes in the “TEST” mode has elapsed, the

previously selected mode is reinstated.

Perishable Mode

Dehumidification

Control (% RH)

Cd33

Cd34

Economy Mode

(On--Off)

Economy mode is a user selectable mode of operation provided for power saving

purposes.

Bulb mode is a user selectable mode of operation that is an extension of dehu-

midification control (Cd33). If dehumidification is set to “Off,” code Cd35 will

display “Nor” and the user will be unable to change it. After a dehumidification

set point has been selected and entered for code Cd33, the user may then change

code Cd35 to “bulb.” After bulb has been selected and entered, the user may then

utilize function codes Cd36 and Cd37 to make the desired changes.

Cd35 Bulb Mode

This code is enabled only if in the dehumidification mode (code Cd33) and bulb

mode (Cd35) has been set to “bulb”. If these conditions are not met, “alt” will be

displayed (indicating that the evaporator fans will alternate their speed) and the

display cannot be changed. If a dehumidification set point has been selected along

with bulb mode then “alt” may be selected for alternating speed, “Lo” for low

speed evaporator fan only, or “Hi” for high speed evaporator fan only. If a setting

other than “alt” has been selected and bulb mode is deactivated in any manner,

then selection reverts back to “alt.”

Evaporator Speed

Select

Cd36

This code, as with function code Cd36, is used with bulb mode and dehumidifica-

tion. If bulb mode is active, this code allows the user to change the temperature

defrost will terminate. It allows the user to change the setting within a range of

4_C to 25.6_C in 0.1_C (0.2_F) increments. This value is changed using the UP/

DOWN ARROW keys, followed by the ENTER key when the desired value is

displayed. If bulb mode is deactivated, the DTS setting returns to the default.

Defrost Termination

Temperature Setting

(Bulb Mode)

Cd37

Cd38

Dis play Only Functions -- Continued

Code Cd38 will display the current secondary supply temperature sensor reading

for units configured for four probes. If the unit is configured with a DataCORD-

Secondary Supply

Temperature Sensor ER, Cd38 will display “-- -- -- -- -- .” If the DataCORDER suffers a failure,

(AL55) Cd38 will display the supply recorder sensor reading.

Code Cd39 will display the current secondary return temperature sensor reading

for units configured for four probes. If the unit is configured with a DataCORD-

Secondary Return

Cd39

Cd40

Temperature Sensor ER, Cd39 will display “-- -- -- -- -- .” If the DataCORDER suffers a failure,

(AL55) Cd39 will display the return recorder sensor reading.

Code Cd40 is configured at commissioning to read a valid container identifica-

Container Identifica-

tion Number

tion number. The reading will not display alpha characters, only the numeric por-

tion of the number will display.

SERVICE FUNCTION: This code is used for troubleshooting and allows manu-

al positioning of the economizer, unloader, suction modulation and oil return

valves. Refer to paragraph 6.19 for operating instructions.

Cd41 Valve Override

Cd42 Oil Return Valve

The status of the valve is displayed (Open - Closed).

T-309

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Table 3-6 Controller Alarm Indications (Sheet 1 of 4)

DESCRIPTION

Code

No.

TITLE

Alarm 13 is triggered if the control module has lost communication with the ex-

pansion module for more than five minutes or communication fails within the

first 15 seconds on power up. This alarm triggers failure action C (evaporator fan

only) or D (all machinery off) of Function Code Cd29 if the unit has a perishable

set point. Failure action D (all machinery off) is triggered if the unit has a frozen

set point

AL13 Expansion Module

Alarm 14 is triggered if the electronic phase detection system is unable to deter-

mine the correct phase relationship. DIRCHECK will be displayed while the

relationship is determined. If the system is unable to determine the proper rela-

tionship alarm 14 will remain active. Additiotnal information on phase detection

may be displayed at Function Code Cd41. If the right most digit of Code Cd41 is

3 or 4, this indicates incorrect motor or sensor wiring. If the right most digit is 5,

this indicates a failed current sensor assembly.

Phase Sequence

AL14

Failure -- Electronic

AL15 Loss Cooling

Future Expansion

Alarm 16 is triggered if compressor current draw is 15% over calculated maxi-

mum for 10 minutes out of the last hour. The alarm is display only and will trig-

ger off when the compressor operates for one hour without over current.

Compressor Current

AL16

High

Alarm 17 is triggered if a compressor start in both directions fails to generate

sufficient pressure differential. The controller will attempt restart every twenty

minutes and deactivate the alarm if successful. This alarm triggers failure action

C (evaporator fan only) or D (all machinery off) of Function Code Cd29 if the

unit has a perishable set point. Failure action D (all machinery off) is triggered if

the unit has a frozen set point

Phase Sequence

AL17

Failure -- Pressure

Alarm 18 is triggered if discharge pressure is 10% over calculated maximum for

10 minutes within the last hour. The alarm is display only and will trigger off

when the compressor operates for one hour without overpressure.

Discharge Pressure

AL18

High

Alarm 19 is triggered if discharge temperature exceeds 135_C (275_F) for 10

minutes within the last hour. The alarm is display only and will trigger off when

the compressor operates for one hour without over temperature.

Discharge Tempera-

ture High

AL19

Alarm 20 is triggered by control power fuse (F3) opening and will cause the soft-

ware shutdown of all control units. This alarm will remain active until the fuse is

replaced.

Control Circuit Fuse

AL20

Open (24 vac)

Alarm 21 is triggered by one of the fuses (F1/F2) being opened on 18 volts AC

power supply to the Controller. The suction modulation valve (SMV) will be

opened and current limiting is halted. Temperature control will be maintained by

cycling the compressor.

Micro Circuit Fuse

AL21

Open (18 vac)

Alarm 22 responds to the evaporator motor internal protectors. The alarm is trig-

gered by opening of either internal protector. It will disable all control units until

the motor protector resets and the unit is power cycled.

Evaporator Fan Mo-

tor Safety

AL22

Alarm 23 is triggered if low current draw is detected on phase B and IPCP, HPS

or IPEM is not tripped. If the compressor should be running, the controller will

initiate a start up every five minutes and trigger off if current reappears. If the

evaporator fan motors only should be running, the alarm will trigger off is cur-

rent reappears. This alarm triggers failure action C (evaporator fan only) or D

(all machinery off) of Function Code Cd29 if the unit has a perishable set point.

Failure action D (all machinery off) is triggered if the unit has a frozen set point

AL23 Loss of Phase B

Alarm 24 is triggered when compressor is not drawing any current. It also trig-

gers failure action ”C” or ”D” set by function Code 29 for perishable setpoint, or

”D” for frozen setpoint. This alarm will remain active until compressor draws

current.

Compressor Motor

AL24

Safety

T-309

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Table 3-6 Controller Alarm Indications (Sheet 2 of 4)

Alarm 25 is triggered by the opening of the condenser motor internal protector

and will disable all control units except for the evaporator fans. This alarm will

remain active until the motor protector resets. This alarm triggers failure action

C (evaporator fan only) or D (all machinery off) of Function Code Cd29 if the

unit has a perishable set point. Failure action D (all machinery off) is triggered if

the unit has a frozen set point

Condenser Fan Mo-

tor Safety

AL25

AL26

AL27

All Supply and Re- Alarm 26 is triggered if the Controller determines that all of the control sensors

turn temperature

Control Sensors

Failure

are out-of-range. This can occur for box temperatures outside the range of --50_C

to +70_C (--58_F to +158_F). This alarm triggers the failure action code set by

Function Code Cd29.

The Controller has a built-in Analog to Digital (A-D) converter, used to convert

analog readings (i.e. temperature sensors, current sensors, etc.) to digital read-

ings. The Controller continuously performs calibration tests on the A-D con-

verter. If the A-D converter fails to calibrate for 30 consecutive seconds, this

alarm is activated.This alarm will be inactivated as soon as the A-D converter

calibrates.

A/D Accuracy Fail-

ure

Alarm 28 is triggered if suction pressure is below 2 psia and alarm 66 (Suction

Pressure Transducer Failure) is not active. This alarm will be inactivated when

suction pressure rises above 2 psia for three continuous minutes. This alarm trig-

gers failure action C (evaporator fan only) or D (all machinery off) as determined

by User Selectable Failure Response if the unit has a perishable set point; Failure

action D (all machinery off) if the unit has a frozen set point. Reset SMV.

Low Suction Pres-

sure

AL28

During start-up diagnostics, the EEPROM is examined to determine validity of

its contents. This is done by testing the set point and the alarm list. If the con-

tents are invalid, Alarm 51 is activated. During control processing, any operation

involving alarm list activity that results in an error will cause Alarm 51 to be ac-

tivated. Alarm 51 is a “display only” alarm and is not written into the alarm list.

Pressing the ENTER key when “CLEAr” is displayed will result in an attempt to

clear the alarm list. If that action is successful (all alarms are inactive), Alarm 51

will be reset.

AL51 Alarm List Failure

Alarm 52 is activated whenever the alarm list is determined to be full; at start-up

or after recording an alarm in the list. Alarm 52 is displayed, but is not recorded

in the alarm list. This alarm can be reset by clearing the alarm list. This can be

done only if all alarms written in the list are inactive.

AL52 Alarm List Full

Alarm 53 is caused by the battery pack charge being too low to provide sufficient

power for battery-backed recording. Renew replaceable batteries. If this alarm

occurs on start up, allow a unit fitted with rechargeable batteries to operate for up

to 24 hours to charge rechargeable batteries sufficiently to deactivate the alarm

AL53 Battery Pack Failure

Alarm 54 is activated by an invalid primary supply temperature sensor reading

that is sensed outside the range of --50 to +70_C (--58_F to +158_F) or if the

probe check logic has determined there is a fault with this sensor. If Alarm 54 is

activated and the primary supply is the control sensor, the secondary supply sen-

sor will be used for control if the unit is so equipped. If the unit does not have a

secondary supply temperature sensor, and AL54 is activated, the primary return

sensor reading, minus 2_C will be used for control.

Primary Supply

Temperature Sensor

Failure (STS)

AL54

AL55

NOTE

The P5 Pre-Trip test must be run to inactivate the alarm

This alarm activates to indicate the DataCORDER has a software failure. To

clear this alarm, reconfigure the unit to the current model number. This failure

may be the result of a voltage dip in access of 25%.

DataCORDER

Failure

T-309

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Table 3-6 Controller Alarm Indications (Sheet 3 of 4)

Alarm 56 is activated by an invalid primary return temperature sensor reading

that is outside the range of --50 to +70_C (--58_F to +158_F). If Alarm 56 is acti-

vated and the primary return is the control sensor, the secondary return sensor

will be used for control if the unit is so equipped. If the unit is not equipped with

a secondary return temperature sensor or it fails, the primary supply sensor will

be used for control.

Primary Return

Temperature Sensor

Failure (RTS)

AL56

NOTE

The P5 Pre-Trip test must be run to inactivate the alarm.

Ambient Tempera-

ture Sensor Failure

Alarm 57 is triggered by an ambient temperature reading outside the valid range

AL57

AL58

from --50_C (--58_F) to +70_C (+158_F).

Alarm 58 is triggered when the compressor high discharge pressure safety switch

remains open for at least one minute. This alarm will remain active until the pres-

sure switch resets, at which time the compressor will restart.

Compressor High

Pressure Safety

Alarm 59 is triggered by the opening of the heat termination thermostat and will

result in the disabling of the heater. This alarm will remain active until the ther-

mostat resets.

Heat Termination

Thermostat

AL59

Alarm 60 is an indication of a probable failure of the defrost temperature sensor

(DTS). It is triggered by the opening of the heat termination thermostat (HTT) or

the failure of the DTS to go above set point within two hours of defrost initia-

tion. After one-half hour with a frozen range set point, or one-half hour of contin-

uous compressor run time, if the return air falls below 7_C (45_F), the Controller

checks to ensure the DTS reading has dropped to 10_C or below. If not, a DTS

failure alarm is given and the defrost mode is operated using the return tempera-

ture sensor. The defrost mode will be terminated after one hour by the Controller.

Defrost Temperature

Sensor Failure

AL60

Alarm 61 is triggered by detection of improper amperage resulting from heater

activation or deactivation. Each phase of the power source is checked for proper

amperage.This alarm is a display alarm with no resulting failure action, and will

be reset by a proper amp draw of the heater.

AL61 Heaters Failure

Alarm 62 is triggered by improper current draw increase (or decrease) resulting

from compressor turn on (or off). The compressor is expected to draw a mini-

mum of 2 amps; failure to do so will activate the alarm. This is a display alarm

with no associated failure action and will be reset by a proper amp draw of the

compressor.

Compressor Circuit

Failure

AL62

Alarm 63 is triggered by the current limiting system. If the compressor is ON

and current limiting procedures cannot maintain a current level below the user

selected limit, the current limit alarm is activated. This alarm is a display alarm

and is inactivated by power cycling the unit, changing the current limit via the

code select Cd32, or if the current decreases below the activation level.

AL63 Current Over Limit

Alarm 64 is triggered if the discharge temperature sensed is outside the range of

-- 6 0 _C (--76_F) to 175_C (347_F), or if the sensor is out of range. This is a dis-

play alarm and has no associated failure action.

Discharge Tempera-

AL64

ture Over Limit

Discharge Pressure Alarm 65 is triggered if a compressor discharge transducer is out of range. This is

AL65

AL66

Transducer Failure

a display alarm and has no associated failure action.

Suction Pressure

Alarm 66 is triggered if a suction pressure transducer is out of range. This is a

display alarm and has no associated failure action.

Transducer Failure

Alarm 67 is triggered by a humidity sensor reading outside the valid range of 0%

to 100% relative humidity. If alarm AL67 is triggered when the dehumidification

mode is activated, then the dehumidification mode will be deactivated.

Humidity Sensor

Failure

AL67

AL69

Alarm 69 is triggered by a suction temperature sensor reading outside the valid

range of --60_C (--76_F) to 150_C (302_F). This is a display alarm and has no

associated failure action.

Suction Temperature

Sensor Failure

T-309

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Table 3-6 Controller Alarm Indications (Sheet 4 of 4)

NOTE

If the Controller is configured for four probes without a DataCORDER, the DataCORDER alarms AL70

and AL71 will be processed as Controller alarms AL70 and AL71. Refer to Table 3-10.

The Controller performs self-check routines. if an internal failure occurs, an

“ERR” alarm will appear on the display. This is an indication the Controller

needs to be replaced.

ERROR

DESCRIPTION

Indicates that the Controller working memory has

failed.

ERR 0 -- RAM failure

EER 1 -- Program

Memory failure

Indicates a problem with the Controller program.

Internal

Microprocessor

Failure

ERR

EER 2 -- Watchdog

time--out

The Controller program has entered a mode whereby

the Controller program has stopped executing.

EER 3 -- On board timer

failure

The on board timers are no longer operational.

Timed items such as; defrost, etc. may not work.

EER 4 -- Internal counter Internal multi-purpose counters have failed. These

failure

counters are used for timers and other items.

The Controller’s Analog to Digital (A-D) converter

has failed.

EER 5 -- A-D failure

Enter Setpoint

(Press Arrow &

Enter)

Entr

StPt

The Controller is prompting the operator to enter a set point.

Low Main Voltage

(Function Codes

Cd27--38 disabled

and NO alarm

stored.)

This message will be alternately displayed with the set point whenever the sup-

ply voltage is less than 75% of its proper value.

T-309

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Table 3-7 Controller Pre-Trip Tes t Codes (Sheet 1 of 4)

Code

No.

TITLE

DESCRIPTION

NOTE

“Auto” or “Auto1” menu includes the: P0, P1, P2, P3, P4, P5, P6 and rSLts. “Auto2” menu

includes P0, P1, P2, P3, P4, P5, P6, P7, P8, P9, P10 and rSLts.

All lights and display segments will be energized for five seconds at the start of

the pre-trip. Since the unit cannot recognize lights and display failures, there are

no test codes or results associated with this phase of pre-trip.

P0--0

Pre-Trip Initiated

Setup: Heater must start in the OFF condition, and then be turned on. A current

draw test is done after 15 seconds.

P1-0 Heaters Turned On

P1-1 Heaters Turned Off

Pass/Fail Criteria: Passes if current draw change is within the range specified.

Setup: Heater must start in the ON condition, and then be turned off. A current

draw test is done after 10 seconds.

Pass/Fail Criteria: Passes if current draw change is within the range specified.

Requirements: Water pressure switch or condenser fan switch input must be

closed.

Setup: Condenser fan is turned ON, a current draw test is done after 15 seconds.

Pass/Fail Criteria: Passes if current draw change is within the range specified.

P2-0

Condenser Fan On

Setup: Condenser fan is turned OFF, a current draw test is done after 10 sec-

onds.

Pass/Fail Criteria: Passes if current draw change is within the range specified.

P2-1 Condenser Fan Off

Low Speed Evapora- Requirements: The unit must be equipped with a low speed evaporator fan, as

tor Fans

determined by the Evaporator Fan speed select configuration variable.

Setup: The high speed evaporator fans will be turned on for 10 seconds, then off

for two seconds, then the low speed evaporator fans are turned on. A current

draw test is done after 60 seconds.

Pass/Fail Criteria: Passes if change in current draw is within the range speci-

fied. Fails if AL11 or AL12 activates during test.

Low Speed Evapora-

tor Fan Motors On

P3-0

Setup: The low speed Evaporator Fan is turned off, a current draw test is done

after 10 seconds.

Low Speed Evapora-

P3-1

P4-0

P4-1

tor Fan Motors Off Pass/Fail Criteria: Passes if change in current draw is within the range speci-

fied. Fails if AL11 or AL12 activates during test.

Setup: The high speed Evaporator Fan is turned on, a current draw test is done

after 60 seconds.

High Speed Evapo-

rator Fan Motors On Pass/Fail Criteria: Passes if change in current draw is within the range speci-

fied. Fails if AL11 or AL12 activates during test.

Setup: The high speed Evaporator Fan is turned off, a current draw test is done

after 10 seconds.

High Speed Evapo-

rator Fan Motors Off Pass/Fail Criteria: Passes if change in current draw is within the range speci-

fied. Fails if AL11 or AL12 activates during test.

Setup: The High Speed Evaporator Fan is turned on and run for eight minutes,

with all other outputs de-energized.

Pass/Fail Criteria: A temperature comparison is made between the return and

supply probes.

Supply/Return Probe

P5-0

Test

NOTE

If this test fails, “P5-0” and “FAIL” will be displayed. If both Probe tests

(this test and the PRIMARY/ SECONDARY) pass, the display will read

“P5” “PASS.”

T-309

3-21

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Table 3-7 Controller Pre-Trip Tes t Codes (Sheet 2 of 4)

Requirements: For units equipped with secondary supply probe only.

Pass/Fail Criteria: The temperature difference between primary and secondary probe

(supply) is compared.

P5-1

Supply Probe Test

NOTE

If this test fails, “P5-1” and FAIL will be displayed. If both Probe tests (this

and the SUPPLY/ RETURN TEST) pass, because of the multiple tests, the

display will read ’P 5’ ’PASS’.

Requirements: For units equipped with secondary return probe only.

Pass/Fail Criteria: The temperature difference between primary and secondary

probe (return) is compared.

NOTES

P5-2

Return Probe Test

1. If this test fails, “P5-2” and “FAIL” will be displayed. If both Probe tests

(this test and the SUPPLY/ RETURN) pass, because of the multiple

tests, the display will read “P 5,” “PASS.”

2. The results of Pre-Trip tests 5-0, 5-1 and 5-2 will be used to activate or

clear control probe alarms.

Setup: The system is operated through a sequence of events to test the compo-

nents. The sequence is: Step 1, de--energize all outputs; Step 2, start unit with

Refrigerant Probes,

Compressor

unloader valve open. Open then close the suction modulation valve. Monitor

suction pressure; Step 3, open suction modulation valve to a known position;

Step 4, close suction modulation valve to a know position; Step 5, open econo-

mizer valve; Step 6, close unloader valve; Step 7, open unloader valve; Step 8,

close economizer valve; Step 9, de--energize all outputs.

and

Refrigeration valves

Discharge

If alarm 64 is activated any time during the first 45 second period of Step 1, the

test fails.

P6-0

P6-1

P6-2

P6-3

P6-4

P6-5

P6-6

Thermistor Test

Suction

Thermistor Test

If alarm 69 is activated any time during the first 45 second period of Step 1, the

test fails.

Discharge Pressure If alarm 65 is activated any time during the first 45 second period of Step 1, the

Sensor Test

test fails.

Suction Pressure

Sensor Test

If alarm 66 is activated any time during the first 45 second period of Step 1, the

test fails.

Compressor Current Compressor current is tested before and after start up. If current does not in-

Draw Test crease, the test fails.

Suction Modulation Suction pressure is measured before and after the valve opens. If suction pres-

Valve Test

sure does not increase, the test fails.

Economizer

Valve Test

Suction pressure is measured during Steps 4 and 5. If suction pressure does not

increase, the test fails.

Suction pressure is measured during Steps 6 and 7. If suction pressure does not

increase, the test fails.

P6-7 Unloader Valve Test

T-309

3-22

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Table 3-7 Temperature Controller Pre-Trip Tes t Codes (Sheet 3 of 4)

NOTE

P7-0 through P10 are included with the “Auto2” only.

NOTE

This test is skipped if the sensed ambient temperature is less than 7_C

(45_F), the return air temperature is less than --17.8_C (0_F), the water

pressure switch is open or the condenser fan switch is open.

P7-0

High Pressure

Switch Closed

Setup: With the unit running, the condenser fan is de-energized, and a 15 minute

timer is started.

Pass/Fail Criteria: The test fails if high pressure switch fails to open in 15 min-

utes.

Requirements: Test P7-0 must pass for this test to execute. Setup: The con-

denser fan is started and a 60 second timer is started.

High Pressure

Switch Open

P7-1

P8-0

Pass/Fail Criteria: Passes the test if the high pressure switch (HPS) closes

within the 60 second time limit, otherwise, it fails.

Setup: If the container temperature is below 15.6°C (60_F), the set point is

changed to 15.6°C, and a 180 minute timer is started. The left display will read

“P8-0.” The control will then heat the container until 15.6°C is reached. If the

container temperature is above 15.6°C at the start of the test, then the test pro-

ceeds immediately to test P8-1 and the left display will change to “P8-1.”

Pass/Fail Criteria: The test fails if the 180 minute timer expires before the con-

trol temperature reaches set point. The display will read “P8-0,” “FAIL.”

Perishable Mode

Heat Test

Requirements: Control temperature must be at least 15.6°C (60_F).

Setup: The set point is changed to 0°C (32_F), and a 180 minute timer is

started. The left display will read “P8-1,” the right display will show the supply

air temperature. The unit will then start to pull down the temperature to the 0°C

set point.

Pass/Fail Criteria: The test passes if the container temperature reaches set point

before the 180 minute timer expires.

Perishable Mode

Pull Down Test

P8-1

Requirements: Test P8-1 must pass for this test to execute. This test is skipped

if the DATAcorder is not configured or available.

Setup: The left display will read “P8-2,” and the right display will show the sup-

ply air temperature. A two hour timer is started. The unit will be required to

maintain the temperature to within + or -- 0.5_C (0.9_F) of set point until a Da-

taCORDER recording is executed. The recorder supply probe temperature run-

ning total (and its associated readings counter) will be zeroed out for the remain-

der of the recording period at the start of this test, so that the actual value

recorded in the DataCORDER will be an average of only this test’s results. Once

a recording interval is complete, the average recorder supply temperature will be

recorded in the DataCORDER, as well as stored in memory for use in applying

the test pass/fail criteria.

Perishable Mode

Maintain Tempera-

ture Test

P8-2

Pass/Fail Criteria: If the recorded temperature is within +/-- 0.5_C. of set point

from test start to DataCORDER recording, the test passes. If the average temper-

ature is outside of the tolerance range at the recording, the test fails and will

auto--repeat by starting P8--0 over.

Setup: The defrost temperature sensor (DTS) reading will be displayed on the

left display. The right display will show the supply air temperature. The unit will

run FULL COOL for 30 minutes maximum until the DTT is considered closed.

Once the DTT is considered closed, the unit simulates defrost by running the

heaters for up to two hours, or until the DTT is considered open.

P9-0

Defrost Test

Pass/Fail Criteria: The test fails if: the DTT is not considered closed after the

30 minutes of full cooling, HTT opens when DTT is considered closed or if re-

turn air temperature rises above 49/50_C (120/122_F).

T-309

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Table 3-7 Controller Pre-Trip Tes t Codes (Sheet 4 of 4)

Setup: If the container temperature is below 7.2_C (45_F), the set point is

changed to 7.2_C and a 180 minute timer is started. The control will then be

placed in the equivalent of normal heating. If the container temperature is above

7.2_C at the start of the test, then the test proceeds immediately to test 10--1.

During this test, the control temperature will be shown in the right display.

Pass/Fail Criteria: The test fails if the 180 minute timer expires before the con-

trol temperate reaches set point --0.3_C (0.17_F). If the test fails it will not auto--

repeat. There is no pass display for this test, once the control temperature reaches

set point, the test proceeds to test 10--1

Frozen Mode

Heat Test

P10-0

P10-1

Requirements: Control temperature must be at least 7.2_C (45_F)

Setup: The set point is changed to --17.8_C (0_F). The system will then attempt

to pull don the Control temperature to set point using normal frozen mode cool-

ing. During this test, the control temperate will be shown on the right display

Pass/Fail Criteria: If the control temperature does not reach set point --0.3_C

(0.17_F) before the 180 minute timer expires the test fails and will auto--repeat

by starting P10--0 over..

Frozen Mode Pull

Down Test

Requirements: Test P10-1 must pass for this test to execute. This test is skipped

if the DATAcorder is not configured or available.

Setup: During this test, the left display will read “P10-2,” and the right display

will show the supply air temperature. A two hour timer is started. The unit will

be required to maintain the temperature to within + 0.5_C (0.9_F)/--1.3_C

(2.3_F) of set point until a DataCORDER recording is executed. The recorder

supply probe temperature running total (and its associated readings counter) will

be zeroed out for the remainder of the recording period at the start of this test, so

that the actual value recorded in the DataCORDER will be an average of only

this test’s results. Once a recording interval is complete, the average recorder

supply temperature will be recorded in the DataCORDER, as well as stored in

memory for use in applying the test pass/fail criteria.

Frozen Mode

Maintain

Temperature Test

P10-2

Pass/Fail Criteria: If the recorded temperature is within +0.5_C (0.9_F)/--1.3_C

(2.3_F) of set point from test start to DataCORDER recording, the test passes. If

the average temperature is outside of the tolerance range at the recording, the test

fails and will auto--repeat by starting P10--0 over.

T-309

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Table 3-8 DataCORDER Function Code As s ignments

NOTE

Inapplicable Functions Display “ -- -- -- -- -- ”

To Acces s : Pres s ALT. MODE key

Code

No.

TITLE

DESCRIPTION

Current reading of the supply recorder sensor.

Current reading of the return recorder sensor.

Recorder Supply

Temperature

dC1

dC2

Recorder Return

Temperature

USDA 1,2,3 Tem-

peratures

dC3-5

Current readings of the three USDA probes.

Current values of the network data points (as configured). Data point 1 (Code

6) is generally the humidity sensor and its value is obtained from the Control-

ler once every minute.

Network Data

Points 1-8

dC6-13

dC14

Cargo Probe 4 Tem-

perature

Current reading of the cargo probe #4.

dC15-19 Future Expansion

These codes are for future expansion, and are not in use at this time.

Current calibration offset values for each of the five probes: supply, return,

USDA #1, #2, and #3. These values are entered via the interrogation pro-

gram.

Temperature Sensors

dC20-24

1-5 Calibration

dC25

Future Expansion

This code is for future expansion, and is not in use at this time..

The DataCORDER serial number consists of eight characters. Function code

dC26 contains the first four characters. Function code dC27 contains the last

four characters. (This serial number is the same as the Controller serial num-

ber)

dC26,27 S/N, Left 4, Right 4

An approximation of the number of logging days remaining until the Data-

CORDER starts to overwrite the existing data.

dC28

dC29

Minimum Days Left

Days Stored

Number of days of data that are currently stored in the DataCORDER.

The date when a Trip Start was initiated by the user. In addition, if the system

goes without power for seven continuous days or longer, a trip start will auto-

matically be generated on the next AC power up.

Date of last Trip

start

dC30

dC31

Shows the current status of the optional battery pack.

PASS: Battery pack is fully charged.

FAIL: Battery pack voltage is low.

Battery Test

dC32

dC33

dC34

Time: Hour, Minute Current time on the real time clock (RTC) in the DataCORDER.

Date: Month, Day

Date: Year

Current date (month and day) on the RTC in the DataCORDER.

Current year on the RTC in the DataCORDER.

Cargo Probe 4

Calibration

Current calibration value for the Cargo Probe. This value is an input via the

interrogation program.

dC35

T-309

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Table 3-9 DataCORDER Pre-Trip Res ult Records

DATA

Tes t

No.

TITLE

1-0

1-1

Heater On

Heater Off

Pass/Fail/Skip Result, Change in current for Phase A, B and C

Pass/Fail/Skip Result, Change in currents for Phase A, B and C

Pass/Fail/Skip Result, Water pressure switch (WPS) -- Open/Closed,

Change in currents for Phase A, B and C

2-0

2-1

3-0

Condenser Fan On

Condenser Fan Off

Pass/Fail/Skip Result, Change in currents for Phase A, B and C

Low Speed Evaporator Fan

Pass/Fail/Skip Result, Change in currents for Phase A, B and C

Low Speed Evaporator Fan

3-1

4-0

4-1

High Speed Evaporator Fan

Pass/Fail/Skip Result, Change in currents for Phase A, B and C

Pass/Fail/Skip Result, STS, RTS, SRS and RRS

5-0

5-1

5-2

6-0

6-1

Supply/Return Probe Test

Secondary Supply Probe Test Pass/Fail/Skip

Secondary Return Probe Test Pass/Fail/Skip

Discharge Thermistor Test

Suction Thermistor Test

Pass/Fail/Skip

Discharge Pressure Sensor

Test

6-2

6-3

6-4

Pass/Fail/Skip

Suction Pressure Sensor Test Pass/Fail/Skip

Compressor Current Draw

Pass/Fail/Skip

Test

6-5

6-6

6-7

Suction Modulation valve Test Pass/Fail/Skip

Economizer Valve Test

Unloader Valve Test

Pass/Fail/Skip

Pass/Fail/Skip Result, AMBS, DPT or CPT (if equipped)

Input values that component opens

7-0

High Pressure Switch Closed

Pass/Fail/Skip Result, STS, DPT or CPT (if equipped)

Input values that component closes

7-1

8-0

8-1

High Pressure Switch Open

Perishable Mode Heat Test

Pass/Fail/Skip Result, STS, time it takes to heat to 16_C (60_F)

Perishable Mode Pull Down

Test

Pass/Fail/Skip Result, STS, time it takes to pull down to 0_C (32_F)

Perishable Mode Maintain

Test

Pass/Fail/Skip Result, Averaged DataCORDER supply temperature

(SRS) over last recording interval.

8-2

9-0

Pass/Fail/Skip Result, DTS reading at end of test, line voltage, line

frequency, time in defrost.

Defrost Test

10-0 Frozen Mode Heat Test

Pass/Fail/Skip Result, STS, time unit is in heat.

10-1 Frozen Mode Pull Down Test Pass/Fail/Skip Result, STS, time to pull down unit to --17.8_C (0_F).

Pass/Fail/Skip Result, Averaged DataCORDER return temperature

10-2 Frozen Mode Maintain Test

(RRS) over last recording interval.

T-309

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Table 3-10 DataCORDER Alarm Indications

To Acces s : Pres s ALT. MODE key

DESCRIPTION

Code No.

TITLE

The supply recorder sensor reading is outside of the range of --50_C to

70_C (--58_F to +158_F) or, the probe check logic has determined there is

a fault with this sensor.

Recorder Supply

Temperature Out of

Range

dAL70

NOTE

The P5 Pre-Trip test must be run to inactivate the alarm.

The return recorder sensor reading is outside of the range of --50_C to

70_C (--58_F to +158_F) or, the probe check logic has determined there is

a fault with this sensor.

Recorder Return Tem-

perature Out of Range

dAL71

NOTE

The P5 Pre-Trip test must be run to inactivate the alarm.

USDA Temperatures The USDA probe temperature reading is sensed outside of --50 to 70°C

1, 2, 3 Out of Range (--58 to 158°F) range.

dAL72-74

dAL75

Cargo Probe 4 Out of The cargo probe temperature reading is outside of --50 to 70°C (--58 to

Range

158°F) range.

dAL76, 77 Future Expansion

These alarms are for future expansion, and are not in use at this time.

The network data point is outside of its specified range. The DataCORD-

ER is configured by default to record the supply and return recorder sen-

sors. The DataCORDER may be configured to record up to 8 additional

network data points. An alarm number (AL78 to AL85) is assigned to

each configured point. When an alarm occurs, the DataCORDER must be

interrogated to identify the data point assigned. When a humidity sensor is

installed, it is usually assigned to AL78.

Network Data Point

dAL78-85

1 -- 8 Out of Range

The Real Time Clock (RTC) backup battery is too low to adequately

maintain the RTC reading.

dAL86

dAL87

RTC Battery Low

RTC Failure

An invalid date or time has been detected. This situation may be corrected

by changing the Real Time Clock (RTC) to a valid value using the Data-

View.

DataCORDER

dAL88

dAL89

A write of critical DataCORDER information to the EEPROM has failed.

EEPROM Failure

An error has been detected in the process of writing daily data to the non-

volatile FLASH memory.

Flash Memory Error

dAL90

dAL91

Future Expansion

Alarm List Full

This alarm is for future expansion, and is not in use at this time.

The DataCORDER alarm queue is determined to be full (eight alarms).

T-309

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SECTION 4

OPERATION

4.1 INSPECTION (Before Starting)

4.3 ADJ UST FRESH AIR MAKEUP VENT

WARNING

The purpose of the fresh air makeup vent is to provide

ventilation for commodities that require fresh air

circulation. The vent must be closed when transporting

frozen foods.

Beware of unannounced starting of the

evaporator and condenser fans. The unit

may cycle the fans and compressor unex-

pectedly as control requirements dictate.

Air exchange depends on static pressure differential,

which will vary depending on the container and howthe

container is loaded.

a. If container is empty, check inside for the following:

1. Check channels or “T” bar floor for cleanliness.

Channels must be free of debris for proper air cir-

culation.

4.3.1 Upper Fres h Air Makeup Vent

2. Check containerpanels, insulation and door seals for

damage. Effect permanent or temporary repairs.

Two slots and a stop are designed into the disc for air

flow adjustments. The first slot allows for a 0 to 30% air

flow, and the second slot allows for a 30 to 100% air

flow. To adjust the percentage of air flow, loosen the

wing nut and rotate the disc until the desired percentage

of air flow matches with the arrow. Tighten the wing

nut. To clear the gap between the slots, loosen the wing

nut until the disc clears the stop. Figure 4-1 gives air

exchange values for an empty container. Higher values

can be expected for a fully loaded container.

3. Visually check evaporator fan motor mounting bolts

for proper securement (refer to paragraph 6.17).

4. Check for dirt or grease on evaporator fan or fan deck

and clean if necessary.

5. Check evaporator coil for cleanliness or obstruc-

tions. Wash with fresh water.

6. Check defrost drain pans and drain lines for obstruc-

tions and clear if necessary. Wash with fresh water.

7. Check panels on refrigeration unit forlooseboltsand

condition of panels. Make sure T.I.R. devices are in

place on access panels.

69NT FRESH AIR MAKEUP

ZERO EXTERNAL STATIC 50HZ

For 60HZ operation multiply curves by 1.2

b. Check condenser coil for cleanliness. Wash with

fresh water.

AIR

FLOW

(CMH)

240

210

180

150

120

c. Open control box door. Check for loose electrical

connections or hardware.

T-BAR

1-!/2”

d. Check color of moisture-liquid indicator.

e. Check oil level in compressor sight glass.

T-BAR

2-%/8”

4.2 CONNECT POWER

T-BAR

3”

WARNING

Do not attempt to remove power plug(s) be-

fore turning OFF start-stop switch (ST),

unit circuit breaker(s) and external power

source.

WARNING

Makesurethepower plugs areclean and dry

before connecting to any power receptacle.

4.2.1 Connection To 380/460 vac Power

1. Make sure start-stop switch (ST, on control panel)

and circuit breaker (CB-1, in the control box) are in

position “0” (OFF).

10 20 30 40 50 60 70 80 90 100

PERCENT OPEN

2. Plug the 460 vac (yellow) cable into a de-energized

380/460 vac, 3-phase power source. Energize the

power source. Place circuit breaker (CB-1) in posi-

tion “I” (ON). Close and secure control box door.

Figure 4-1 Make Up Air Flow Chart

T-309

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4.4 CONNECT REMOTE MONITORING

RECEPTACLE

1. Depress the ALT MODE key and scroll to Code

dC30.

If remote monitoring is required, connect remote

monitor plug at unit receptacle. (See item 9, Figure 2-5.)

When the remote monitor plug is connected to the

remote monitoring receptacle, the following remote

circuits are energized:

2. Depress and hold the ENTER key for five seconds.

3. The “Trip Start” event will be entered in the Data-

CORDER.

4.6.3 Complete Ins pection

Allow unit to run for 5 minutes to stabilize conditions

and perform a pre--trip diagnosis in accordance with the

following paragraph.

CIRCUIT

FUNCTION

Sockets B to A Energizes remote cool light

Sockets C to A Energizes remote defrost light

Sockets D to A Energizes remote in-range light

4.7 PRE-TRIP DIAGNOSIS

CAUTION

4.5 STARTING AND STOPPING INSTRUCTIONS

Pre-trip inspection should not be performed

with critical temperature cargoes in the con-

tainer.

WARNING

Make sure that the unit circuit breaker(s)

(CB-1 & CB-2) and the START-STOP

switch (ST)arein the“O” (OFF)position be-

fore connecting to any electrical power

source.

CAUTION

When Pre-Trip key is pressed, economy, de-

humidification and bulb mode will be deac-

tivated. At the completion of Pre-Trip activi-

ty, economy, dehumidification and bulb

mode must be reactivated.

4.5.1 Starting the Unit

1. With power properly applied, the fresh air damper set

and (if required) the water cooled condenser con-

nected, (refer to paragraphs 4.2 & 4.3) place the

START-STOP switch to “I” (ON).

Pre-Trip diagnosis provides automatic testing of the

unit components using internal measurements and

comparison logic. The program will provide a “PASS”

or “FAIL” display to indicate test results.

NOTE

The testing begins with access to a pre-trip selection

menu. The user may have the option of selecting one of

two automatic tests. These tests will automatically

perform a series of individual pre--trip tests. The user

may also scroll down to select any of the individual

tests. When only the short sequence is configured it will

appear as “AUtO” in the display, otherwise “AUtO1”

will indicate the short sequence and “AUtO2” will

indicate the long sequence. The test short sequence will

run tests P0 through P6. The long test sequence will run

tests P0 through P10.

Within the first 30 seconds the electronic phase

detection system will check for proper com-

pressor rotation. If rotation is not correct, the

compressor will be stopped and restarted in the

opposite direction. If the compressor is produc-

ing unusually loud and continuous noise after

the first 30 seconds of operation, stop the unit

and investigate.

2. Continue with Start Up Inspection, paragraph 4.6.

A detailed description of the pre-trip test codes is listed

in Table 3-7, page 3-21. If no selection is made, the

pre-trip menu selection process will terminate

automatically. However, dehumidification and bulb

mode must be reactivated manually if required.

4.5.2 Stopping the Unit

To stop the unit, place the START-STOP switch in

position “0” (OFF).

4.6 START--UP INSPECTION

Scrolling down to the “rSLts” code and pressing

ENTER will allow the user to scroll through the results

ofthelast pre--trip testing run. If no pre--testing has been

run (or an individual test has not been run) since the unit

was powered up “--------” will be displayed.

4.6.1 Phys ical Ins pection

a. Check rotation of condenser and evaporator fans.

b. Check compressor oil level. (Refer to paragraph 6.9.)

4.6.2 Check Controller Function Codes

To start a pre--trip test, do the following:

Check and, if required, reset controller Function Codes

(Cd27 through Cd39) in accordance with desired

operating parameters. Refer to paragraph 3.2.2.

NOTE

1. Prior to startingtests, verifythat unit voltage

(Function Code Cd 07) is within tolerance

and unit amperage draw (Function Codes

Cd04, Cd05, Cd06) are within expected

limits. Otherwise, tests may fail incorrectly.

DataCORDER

a. Check and, if required, set the DataCORDER Con-

figuration in accordance with desired recording pa-

rameter. Refer to paragraph 3.6.3.

b. Enter a “Trip Start”. To enter a “trip Start”, do the

following:

2. All alarms must be rectified and cleared

before starting tests.

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3. Pre-trip may also be initiated via

communications. The operation is the same

as for the key pad initiation described below

except that should a test fail, the pre-trip

mode will automatically terminate. When

initiated via communications, a test may not

be interrupted with an arrow key, but the

pre-trip mode can be terminated with the

PRE-TRIP key.

the three minute time period expires, the unit will

terminate pre-trip and return to control mode opera-

tion.

2. While the tests are being executed, the user may ter-

minate the pre-trip diagnostics by pressing and hold-

ing the PRE-TRIP key. The unit will then resume

normal operation. If the user decides to terminate a

test but remain at the test selection menu, the user

may press the UP ARROW key. When this is done

all test outputs will be de-energized and the test

selection menu will be displayed.

a. Press the PRE-TRIP key. This accesses a test selec-

tion menu.

3. Throughout the duration of any pre-trip test except

the P-7 high pressure switch tests, the current and

pressure limiting processes are active .

b. TO RUN AN AUTOMATIC TEST: Scroll through

the selections by pressing the UP ARROW or

DOWN ARROW keys to display AUTO, AUTO 1 or

AUTO 2 as desired and then press the AUTO key.

d. Pre-Trip Test Results

At the end of the pre-trip test selection menu, the

message “P,” “rSLts” (pre--trip results) will be

displayed. Pressing the ENTER key will allow the user

to see the results for all subtests (i.e., 1-0, 1-1, etc). The

results will bedisplayed as “PASS”or “FAIL”for all the

tests run to completion since power up. If a test has not

been run since power up, “-- -- -- -- -- ” will be displayed.

Once all pre--test activity is completed,

dehumidification and bulb mode must be reactivated

manually if required.

1. The unit will execute the series of tests without any

need for direct user interface. These tests vary in

length, depending on the component under test.

2. While tests arerunning, “P#-#”will appearon theleft

display, where the #’s indicate the test number and

sub-test. The right display will show a countdown

time in minutes and seconds, indicating how much

time there is left remaining in the test.

CAUTION

4.8 OBSERVE UNIT OPERATION

4.8.1 Probe Check

When a failure occurs during automatic

testing the unit will suspend operation

awaiting operator intervention.

IftheDataCORDER is off orin alarm the controllerwill

revert to a four probe configuration which includes the

DataCORDER supply and return air probes as the

secondary controller probes. The controller

continuously performs probe diagnosis testing which

compares the four probes. If the probe diagnosis result

indicates a probe problem exists, the controller will

perform a probe check to identify the probe(s) in error.

When an automatic test fails, it will berepeated once.

A repeated test failure will cause “FAIL” to be shown

on the right display, with the corresponding test num-

ber to the left. The user may then press the DOWN

ARROWto repeat thetest, theUP ARROWto skip to

the next test or the PRE--TRIP key to terminate test-

ing. The unit will wait indefinitely, until the user

manually enters a command.

a. Probe Diagnostic Logic -- Standard

If the probe check option (controller configuration code

CnF31) is configured for standard, the criteria used for

comparison between theprimary and secondarycontrol

probes is:

CAUTION

When Pre--Trip test Auto 2 runs to comple-

tion without being interrupted, the unit will

terminate pre-trip and display “Auto 2”

“end.” The unit will suspend operation until

the user depresses the ENTER key!

1_C (1.8_F) for perishable set points or 2_C (3.6_F)

for frozen set points.

If25 ormore of30 readings taken within a 30 minute

period are outside of the limit, then a defrost is initi-

ated and a probe check is performed.

When an Auto 1 runs to completion without a failure,

the unit will exit the pre-trip mode, and return to nor-

mal control operation. However, dehumidification

and bulb mode must be reactivated manually if re-

quired.

In this configuration, a probe check will be run as a part

of every normal (time initiated) defrost.

b. Probe Diagnostic Logic -- Special

c. TO RUN AN INDIVIDUAL TEST: Scroll through

the selections by pressing the UP ARROW or

DOWN ARROW keys to display an individual test

code. Pressing ENTER when the desired test code is

displayed.

If the probe check option is configured for special the

abovecriteriaareapplicable. Adefrost with probecheck

will be initiated if 25 of 30 readings or 10 consecutive

readings are outside of the limits

In this configuration, a probe check will not be run as a

part of a normal defrost, but only as a part of a defrost

initiated due to a diagnostic reading outside of the

limits.

c.The30 minutetimerwill be reset at each of the follow-

ing conditions:

1. Individually selected tests, other than the LED/Dis-

play test, will perform the operations necessary to

verify the operation of the component. At the con-

clusion, PASS or FAIL will be displayed. This mes-

sage will remain displayed for up to three minutes,

during which time a user may select another test. If

T-309

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1. At every power up.

Any probe(s) determined to be outside the limits will

cause the appropriate alarm code(s) to be displayed to

identify which probe(s) needs to be replaced. The P5

Pre-Trip test must be run to inactivate alarms.

2. At the end of every defrost.

3. After every diagnostic check that does not fall out-

side of the limits as outlined above.

4.9 SEQUENCE OF OPERATION

d. Probe Check

General operation sequences for cooling, heating and

defrost are provided in the following subparagraphs.

Schematic representation of controller action are

provided in Figure 4-2 and Figure 4-3. Refer to Section 3

for detailed descriptions of special events and timers

that are incorporated by the controller in specific modes

of operation.

A defrost cycle probe check is accomplished by

energizing just the evaporator motors for eight minutes

at the end of the normal defrost. At the end of the eight

minute period the probes will be compared to a set of

predetermined limits. The defrost indicator will remain

on throughout this period.

RISING

TEMPERATURE

PULL DOWN

FALLING

TEMPERATURE

+2.5_C

(4.5_F)

+2.5_C

(4.5_F)

START UNLOADED,

TRANSITION TO

ECONOMIZED

OPERATION

MODULATED

COOLING

UNLOADED

MODULATED

COOLING

UNLOADED

+.20_C

SET POINT

--0.20_C

+.20_C

SET POINT

AIR CIRCULATION

UNLOADED OPERATION

AIR CIRCULATION

--0.20_C

AIR CIRCULATION

HEATING

-- 0 . 5 _C

(0.9_F)

-- 0 . 5 _C

(0.9_F)

HEATING

NOTE: TEMPERATURES INDICATIONS ARE ABOVE OR BELOW SET POINT

Figure 4-2 Controller Operation -- Peris hable Mode

T-309

4-4

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FALLING

TEMPERATURE

RISING

TEMPERATURE

START UNLOADED,

TRANSITION TO

ECONOMIZED

OPERATION

COOLING

ECONOMIZED

+.20_C

SET POINT

--0.20_C

AIR CIRCULATION

NOTE: TEMPERATURES INDICATIONS ARE ABOVE OR BELOW SET POINT

Figure 4-3 Controller Operation -- Frozen Mode

ENERGIZED

DE--ENERGIZED

will switch operation from compressor contactor PB to

compressor contactor PA. Compressor contactors PA is

wired to run the compressor on L1, L2, and L3.

Compressor contactor PB is wired to run the

compressor on L2, L1 and L3 thus providing reverse

rotation .

CONTROL TRANSFORMER

FOR FULL DIAGRAM AND

LEGEND, SEE SECTION 7

POWER TO

CONTROLLER

4.9.2 Sequence Of Operation -- Peris hable Mode

Cooling

NOTE

In the Conventional Perishable Mode of opera-

tion the evaporator motors run in high speed. In

the Economy Perishable Mode the fan speed is

varied.

SIGNAL TO

CONTROLLER

a. With supply air temperature above set point and de-

creasing, the unit will be cooling with the condenser

fan motor (CF), compressor motor (PA or PB), evap-

orator fan motors (EF) energized and the COOL light

illuminated. (See Figure 4-4.) Also, if current or

pressure limiting is not active, the controller will en-

ergize relay TS to open the economizer solenoid

valve (ESV) and place the unit in economized opera-

tion.

USV

ESV

NOTE: HIGH SPEED EVAPORATOR FAN SHOWN. FOR LOW SPEED

CONTACT TE IS DE--ENERGIZED AND CONTACT TV IS ENERGIZED

Figure 4-4 Peris hable Mode

b. When the air temperature decreases to a predeter-

mined tolerance above set point, the in-range light is

illuminated.

4.9.1 Sequence Of operation -- Compres s or Phas e

Sequence

The controller logic will check for proper compressor

rotation. If the compressor is rotating in the wrong

direction, the controller will energize or de--energize

relay T6 as required (see Figure 4-4). Energizing relay

T6 will switch operation from compressor contactor PA

to compressor contactor PB. De--energizing relay T6

c. As the air temperature continues to fall, modulating

cooling starts at approximately 2.5_C (4.5_F) above

set point. (See Figure 4-2.) At set point, relay TS is

de--energized to close the economizer solenoid valve

and relay TU is energized to open the unolader sole-

T-309

4-5

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noid valve changing from economized operation to

unloaded operation. (As shown in Figure 4-5)

rator fans continue to run to circulate air throughout

the container.

c. A safety heater termination thermostat (HTT), at-

tached to an evaporator coil support, will open the

heating circuit if overheating occurs.

d. The controller monitors the supply air. Once the sup-

ply airfalls belowset point the controllerperiodically

records thesupply airtemperature, set point and time.

A calculation is then performed to determine temper-

ature drift from set point over time.

4.9.4 Sequence Of operation -- Frozen Mode Cool-

ing

e. If the calculation determines cooling is no longer re-

quired, contacts TDand TNareopened tode-energize

compressor motor and condenser fan motor. The cool

light is also de-energized.

a. With supply air temperature above set point and de-

creasing, the unit will transition to economized cool-

ing with the condenser fan motor (CF), compressor

motor (CH), economizer solenoid valve (ESV), low

speed evaporator fan motors (ES) energized and the

COOL light illuminated. (See Figure 4-6.)

f. Theevaporatorfan motors continueto run tocirculate

air throughout the container. The in-range light re-

mains illuminated as long as the supply air is within

tolerance of set point.

b.When the air temperature decreases to a predeter-

mined tolerance above set point, the in-range light is

illuminated.

g. If the supply air temperature increases to 0.2_C

(0.4_F) above set point and the three minute off time

has elapsed, relays TD, TU and TN are energized to

restart the compressor and condenser fan motors in

unloaded operation. The cool light is also illumi-

nated.

ENERGIZED

DE--ENERGIZED

CONTROL TRANSFORMER

FOR FULL DIAGRAM AND

LEGEND, SEE SECTION 7

POWER TO

CONTROLLER

ENERGIZED

DE--ENERGIZED

CONTROL TRANSFORMER

FOR FULL DIAGRAM AND

LEGEND, SEE SECTION 7

POWER TO

CONTROLLER

SIGNAL TO

CONTROLLER

USV

ESV

Figure 4-6 Frozen Mode

SIGNAL TO

CONTROLLER

USV

c. When the return air temperature decreases to 0.2_C

(0.4_F) below set point, contacts TD, TS and TN are

opened to de-energize the compressor, economizer

solenoid valve and condenser fan motors. The cool

light is also de-energized.

ESV

NOTE: HIGH SPEED EVAPORATOR FAN SHOWN. FOR LOW SPEED

CONTACT TE IS DE--ENERGIZED AND CONTACT TV IS ENERGIZED

d. The evaporator fan motors continue to run in low

speed to circulate air throughout the container. The

in-range light remains illuminated as long as the re-

turn air is within tolerance of set point.

Figure 4-5 Peris hable Mode Heating

4.9.3 Sequence Of Operation --

Peris hable Mode Heating

e. When return air temperature is 10_C (18_F) or more

below set point, the evaporator fans are brought to

high speed.

a. If the air temperature decreases 0.5_C (0.9_F) below

set point, the system enters the heating mode. (See

Figure 4-2). The controller closes contacts TH (see

Figure 4-5) to allow power flow through the heat ter-

mination thermostat (HTT) to energize the heaters

(HR). TheHEATlight is alsoilluminated. Theevapo-

rator fans continue to run to circulate air throughout

the container.

f. When the return air temperature increases to 0.2_C

(0.4_F) above set point and the three minute off time

has elapsed, relays TD, TS and TN are energizes to

restart the compressor and condenserfan motors. The

cool light is illuminated.

4.9.5 Sequence Of Operation -- Defros t

b. When the temperature rises to 0.2_C (0.4_F) above

set point, contact TH opens to de--energize the heat-

ers. The HEAT light is also de--energized. The evapo-

The defrost cycle may consist of up to three distinct

operations. The first is de-icing of the coil, the second is

a probe check cycle and the third is snap freeze.

T-309

4-6

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Defrost may be initiated by any one of the following

methods:

If the controller is programmed with the Lower DTT

setting option the defrost termination thermostat set

point may beconfigured to the default of 25.6_C (78_F)

orlowered to 18_C (64_F). When arequestfor defrostis

made by use of the manual defrost switch,

communications or probe check the unit will enter

defrost if the defrost temperature thermostat reading is

at or below the defrost termination thermostat setting.

Defrost will terminate with the defrost temperature

sensor reading rises above the defrost termination

thermostat setting. When a request for defrost is made

by the defrost intermale timer or by demand defrost, the

defrost temperature setting setting must be below 10_C

(50_F).

1. The manual defrost switch (MDS) is closed by the

user.

2. The user sends a defrost command by communica-

tions.

3. The defrost interval timer (controller function code

Cd27) reaches the defrost interval set by the user.

4. The controller probe diagnostic logic determines

that a probe check is necessary based on the tempera-

ture values currently reported by the supply and re-

turn probes.

5. If the controller is programmed with the Demand

Defrost option (Future) and the option is set to “IN”

the unit will enter defrost if it has been in operation

for over 2.5 hours without reaching set point.

When the defrost mode is initiated the controller opens

contacts TD, TN and TE (or TV) to de-energize the

compressor, condenser fan and evaporator fans. The

COOL light is also de--energized.

ENERGIZED

The controller then closes TH to supply power to the

heaters. The defrost light is illuminated.

DE--ENERGIZED

CONTROL TRANSFORMER

FOR FULL DIAGRAM AND

LEGEND, SEE SECTION 7

When the defrost temperature sensor reading rises to the

defrost termination thermostat setting, the de--icing

operation is terminated.

POWER TO

CONTROLLER

If defrost does not terminate correctly and temperature

reaches the set point of the heat termination thermostat

(HTT) the thermostat will open to de--energize the

heaters. If termination does not occur within 2.0 hours,

the controller will terminate defrost. An alarm will be

given of a possible DTS failure.

If probe check (controller function code CnF31) is

configured to special, the unit will proceed to the next

operation (snap freeze or terminate defrost). If the code

is configured to standard, the unit will perform a probe

check. The purpose of the probe check is to detect

malfunctions or drift in the sensed temperature that is

too small to be detected by the normal sensor out of

range tests. The system will run for eight minutes in this

condition. At the end of the eight minutes, probe alarms

will be set or cleared based on the conditions seen.

SIGNAL TO

CONTROLLER

USV

ESV

Figure 4-7 Defros t

Defrost may be initiated any time the defrost

temperature sensor reading falls below the controller

defrost termination thermostat set point. Defrost will

terminate when the defrost temperature sensor reading

rises above the defrost termination thermostat set point.

The defrost termination thermostat is not a physical

component. It is a controller setting that acts as a

thermostat, “closing” (allowing defrost) when the

defrost temperature sensor reading is below the set point

and “opening”(terminating orpreventing defrost)when

the sensor temperature reading is above set point. When

the unit is operating in bulb mode (refer to paragraph

3.3.9), special settings may be applicable.

When the return air falls to 7_C (45_F), the controller

checks to ensure the defrost temperature sensor (DTS)

reading has dropped to 10_C or below. If it has not, a

DTS failure alarm is given and the defrost mode is

operated by the return temperature sensor (RTS).

If controller function code CnF33 is configured to snap

freeze, the controller will sequence to this operation.

The snap freeze consists of running the compressor

without the evaporator fans in operation for a period of

four minutes with the suction modulation valve fully

open. When the snap freeze is completed, defrost is

formally terminated.

T-309

4-7

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SECTION 5

TROUBLESHOOTING

REMEDY/

REFERENCE

SECTION

CONDITION

POSSIBLE CAUSE

5.1 UNIT WILL NOT START OR STARTS THEN STOPS

External power source OFF

Turn on

Check

Replace

Check

6.17

Start-Stop switch OFF or defective

Circuit breaker tripped or OFF

Circuit breaker OFF or defective

Control transformer defective

Fuse (F3) blown

No power to unit

Loss of control power

Start-Stop switch OFF or defective

Evaporator fan motor internal protector open

Condenser fan motor internal protector open

Compressor internal protector open

High pressure switch open

6.12

6.8

5.7

Component(s) Not Operating

Heat termination thermostat open

Loss of communication with expansion module

Malfunction of current sensor

Low line voltage

Replace

Check Wiring

Replace

Check

6.8

Single phasing

Compressor hums, but does not

start

Shorted or grounded motor windings

Compressor seized

6.8

5.2 UNIT OPERATES LONG OR CONTINUOUSLY IN COOLING

Hot load

Normal

Repair

6.7.1

Container

Defective box insulation or air leak

Shortage of refrigerant

Evaporator coil covered with ice

Evaporator coil plugged with debris

Evaporator fan(s) rotating backwards

Defective evaporator fan motor/capacitor

Air bypass around evaporator coil

Controller set too low

5.6

6.15

6.15/6.17

6.18

Check

Reset

Compressor service valves or liquid line shutoff valve par- Open valves

Refrigeration System

tially closed

completely

Dirty condenser

6.11

Compressor worn

6.8

Current limit (function code Cd32) set to wrong value

Suction modulation valve lost track of step count

Suction modulation valve malfunction

Economizer solenoid valve or TXV malfunction

Unloader valve stuck open

3.5.5

Power cycle

6.20

6.14, 6.19

6.19

T-309

5-1

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REMEDY/

REFERENCE

SECTION

CONDITION

POSSIBLE CAUSE

5.3 UNIT RUNS BUT HAS INSUFFICIENT COOLING

Abnormal pressures

Abnormal temperatures

Abnormal currents

5.7

5.15

5.16

Controller malfunction

5.9

Evaporator fan or motor defective

6.17

Shortage of refrigerant

6.7.1

Power cycle

6.20

Refrigeration System

Suction modulation valve lost track of step count

Suction modulation valve malfunction

Compressor service valves or liquid line shutoff valve par- Open valves

tially closed

completely

6.14, 6.19

6.19

Economizer solenoid valve or TXV malfunction

Unloader valve stuck open

Frost on coil

5.10

5.4 UNIT WILL NOT HEAT OR HAS INSUFFICIENT HEATING

Start-Stop switch OFF or defective

Check

Turn ON

Replace

6.17

Circuit breaker OFF or defective

External power source OFF

No operation of any kind

Circuit breaker or fuse defective

Control Transformer defective

Evaporator fan internal motor protector open

Heat relay defective

No control power

Check

6.15

Heater termination thermostat open

Heater(s) defective

6.15

Heater contactor or coil defective

Evaporator fan motor(s) defective or rotating backwards

Evaporator fan motor contactor defective

Controller malfunction

Replace

6.15/6.17

Replace

5.9

Unit will not heat or has insuffi-

cient heat

Defective wiring

Replace

Tighten

2.3

Loose terminal connections

Low line voltage

5.5 UNIT WILL NOT TERMINATE HEATING

Controller improperly set

Reset

5.9

Controller malfunction

Unit fails to stop heating

Heater termination thermostat remains closed along with

the heat relay

6.15

5.6 UNIT WILL NOT DEFROST PROPERLY

Defrost timer malfunction (Cd27)

Table 3-5

Tighten/

Replace

Loose terminal connections

Defective wiring

Will not initiate defrost

automatically

Defrost temperature sensor defective or heat termination

thermostat open

Replace

Heater contactor or coil defective

T-309

5-2

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REMEDY/

REFERENCE

SECTION

CONDITION

POSSIBLE CAUSE

5.6 UNIT WILL NOT DEFROST PROPERLY -- Continued

Manual defrost switch defective

Defrost temperature sensor open

Replace

4.9.5

Will not initiate defrost

manually

Initiates but relay (DR) drops

out

Low line voltage

2.3

Heater contactor or coil defective

Heater(s) burned out

Wet load

Replace

6.15

Initiates but does not defrost

Frequent defrost

Normal

5.7 ABNORMAL PRESSURES (COOLING)

Condenser coil dirty

6.11

6.12

6.7.1

Open

6.20

Replace

Open

6.13

6.7.1

6.14

6.15

5.6

Condenser fan rotating backwards

Condenser fan inoperative

High discharge pressure

Refrigerant overcharge or noncondensibles

Discharge service valve partially closed

Suction modulation valve malfunction

Faulty suction pressure transducer

Suction service valve partially closed

Filter-drier partially plugged

Low refrigerant charge

Expansion valve defective

Low suction pressure

No evaporator air flow or restricted air flow

Excessive frost on evaporator coil

Evaporator fan(s) rotating backwards

Suction modulation valve malfunction

2.3

6.20

Suction and discharge pressures

tend to equalize when unit is

operating

Compressor operating in reverse

Compressor cycling/stopped

5.14

Check

5.8 ABNORMAL NOISE OR VIBRATIONS

Compressor start up after an extended shutdown

Normal

Brief chattering when manually shut down

Compressor operating in reverse

Loose mounting bolts or worn resilient mounts

Loose upper mounting

5.14

Tighten/Replace

6.8.1 step r.

6.14

Compressor

Liquid slugging

Insufficient oil

6.9

Bent, loose or striking venturi

Worn motor bearings

Check

6.12/6.17

Condenser or Evaporator Fan

Bent motor shaft

T-309

5-3

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REMEDY/

REFERENCE

SECTION

CONDITION

POSSIBLE CAUSE

5.9 CONTROLLER MALFUNCTION

Defective Sensor

Defective wiring

Fuse (F1, F2, F3) blown

6.22

Check

Replace

Will not control

Stepper motor suction modulation valve circuit malfunction 6.20

Low refrigerant charge

6.7

5.10 NO EVAPORATOR AIR FLOW OR RESTRICTED AIR FLOW

Frost on coil

5.6

Evaporator coil blocked

Dirty coil

6.15

6.17

Replace

Evaporator fan motor internal protector open

Evaporator fan motor(s) defective

No or partial evaporator air flow

Evaporator fan(s) loose or defective

Evaporator fan contactor defective

5.11 THERMOSTATIC EXPANSION VALVE MALFUNCTION

Low refrigerant charge

6.7.1

Open

External equalizer line plugged

Wax, oil or dirt plugging valve or orifice Ice formation at

valve seat

6.14

Low suction pressure with high

superheat

Superheat not correct

6.7.1

Power assembly failure

Loss of element/bulb charge

Broken capillary

6.14

Foreign material in valve

Superheat setting too low

External equalizer line plugged Ice holding valve open

Foreign material in valve

6.14

Open

6.14

High suction pressure with low

superheat

Pin and seat of expansion valve eroded or held open by for-

eign material

Liquid slugging in compressor

Fluctuating suction pressure

6.14

Improper bulb location or installation

Low superheat setting

5.12 AUTOTRANSFORMER MALFUNCTION

Circuit breaker (CB-1 or CB-2) tripped

Power source not turned ON

Check

Unit will not start

5.13 WATER-COOLED CONDENSER OR WATER PRESSURE SWITCH

Water pressure switch malfunction

Check

Condenser fan starts and stops

Water supply interruption

T-309

5-4

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REMEDY/

REFERENCE

SECTION

CONDITION

POSSIBLE CAUSE

5.14 COMPRESSOR OPERATING IN REVERSE

CAUTION

Allowing the scroll compressor to operate in reverse for more than two minutes will result in internal

compressor damage. Turn the start--stop switch OFF immediately.

Incorrect wiring of compressor

Incorrect wiring of compressor contactor(s)

Incorrect wiring of current sensor

Electrical

Check

5.15 ABNORMAL TEMPERATURES

Discharge temperature sensor drifting high

Replace

Failed economizer, TXV or solenoid valve

Plugged economizer, TXV or solenoid valve

Loose or insufficiently clamped sensor

Failed liquid injection solenoid valve

Discharge temperature sensor drifting low

Loose or insufficiently clamped sensor

High discharge temperature

Low suction temperature

5.16 ABNORMAL CURRENTS

Unit reads abnormal currents

Current sensor wiring

Check

T-309

5-5

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SECTION 6

SERVICE

NOTE

To avoid damage to the earth’s ozone layer, use a refrigerant recovery system whenever removing refrigerant.

When working with refrigerants you must comply with all local government environmental laws. In the

U.S.A., refer to EPA section 608.

WARNING

Never use air for leak testing. It has been de-

termined that pressurized, mixtures of re-

frigerant and air can undergo combustion

when exposed to an ignition source.

6.1 SECTION LAYOUT

Service procedures are provided herein beginning with

refrigeration system service, then refrigeration system

component service, electrical system service,

temperature recorder service and general service. Refer

to the Table Of Contents to locate specific topics.

VALVE

BACKSEATED

VALVE

FRONTSEATED

(Clockwise)

(Counterclockwise)

1. Line Connection

2. Access Valve

3. Stem Cap

4. Valve stem

5. Compressor Inlet

Connection

6.2 SERVICE VALVES

The compressor suction, compressor discharge,

compressor economizer, oil return and the liquid line

service valves (see Figure 6-1) are provided with a

double seat and an access valve which enable servicing

of the compressor and refrigerant lines. Turning the

valve stem clockwise (all the way forward) will

frontseat the valve to close off the line connection and

open a path to the access valve. Turning the stem

counterclockwise (all the way out) will backseat the

valve to open the line connection and close off the path

to the access valve.

Figure 6-2 Suction Service Valve

DISCHARGE

PRESSURE

GAUGE

SUCTION

PRESSURE

GAUGE

With the valve stem midway between frontseat and

backseat, both of the service valve connections are open

to the access valve path.

OPENED (Backseated )

HAND VALVE

CLOSED (Frontseated)

HAND VALVE

For example, the valve stem is first fully backseated

when connecting amanifold gaugeto measurepressure.

Then, the valve is opened 1/4 to 1/2 turn to measure the

pressure.

A. CONNECTION TO LOW SIDE OF SYSTEM

B. CONNECTION TO EITHER:

REFRIGERANT CYLINDER OR

OIL CONTAINER

C. CONNECTION TO HIGH SIDE OF SYSTEM

Figure 6-3 Manifold Gauge Set

6.3. MANIFOLD GAUGE SET

The manifold gauge set (see Figure 6-3) is used to

determine system operating pressure, add refrigerant

charge, and to equalize or evacuate the system.

VALVE

BACKSEATED

(Counterclockwise)

VALVE

FRONTSEATED

(Clockwise)

When the suction pressure hand valve is frontseated

(turned all the way in), the suction (low) pressure can be

checked. When the discharge pressure hand valve is

frontseated, the discharge (high) pressure can be

checked. When both valves are open (turned

counter-clockwise all the way out), high pressure vapor

will flow into the low side. When the suction pressure

valve is open and the discharge pressure valve shut, the

1. Line Connection

2. Access Valve

3. Stem Cap

4. Valve stem

5. Compressor Or Filter

Drier Inlet Connection

Figure 6-1 Service Valve

T-309

6-1

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system can be charged. Oil can also be added to the

system.

2. Connect the field service coupling (see Figure 6-4)

to the access valve.

3. Turn the field service coupling knob clockwise,

which will open the system to the gauge set.

A R-134a manifold gauge/hose set with self-sealing

hoses (see Figure 6-4) is required for service of the

models covered within this manual. The manifold

gauge/hose set is available from Carrier Transicold.

(Carrier Transicold P/N 07-00294-00, which includes

items 1 through 6, Figure 6-4.)To perform serviceusing

the manifold gage/hose set, do the following:

4. To read system pressures: slightly midseat the ser-

vice valve.

5. Repeat the procedure to connect the other side of the

gauge set.

a. Preparing Manifold Gauge/Hose Set For Use

CAUTION

To prevent trapping liquid refrigerant in the

manifold gauge set be sure set is brought to

suction pressure before disconnecting.

1. Ifthemanifold gauge/hoseset is newor was exposed

to the atmosphere it will need to be evacuated to

remove contaminants and air as follows:

2. Back seat (turn counterclockwise )both field service

couplings (see Figure 6-4) and midseat both hand

valves.

c. Removing the Manifold Gauge Set

1. While the compressor is still ON, backseat the high

side service valve.

3. Connect the yellow hose to a vacuum pump and re-

frigerant 134a cylinder.

2. Midseat both hand valves on the manifold gauge set

and allow the pressure in the manifold gauge set to

bedrawn down to lowsidepressure. This returns any

liquid that may bein thehigh sidehoseto thesystem.

SUCTION

PRESSURE

GAUGE

DISCHARGE

PRESSURE

GAUGE

3. Backseat the low side service valve. Backseat both

field service couplings and frontseat both manifold

set valves. Remove the couplings from the access

valves.

CLOSED

OPENED

(Frontseated)

HAND VALVE

(Backseated )

HAND VALVE

4. Install both service valve stem caps and service port

caps (finger-tight only).

To High Side

Access Valve

To Low Side

Access Valve

6.4 PUMPING THE UNIT DOWN

To service the filter-drier, economizer, expansion

valves, moisture-liquid indicator, suction modulation

valve, economizer solenoid valve, unloader solenoid

valve or evaporator coil, pump the refrigerant into the

high side as follows:

BLUE

RED

YELLOW

CAUTION

Red Knob

Blue Knob

The scroll compressor achieves low suction

pressure very quickly. Do not operate the

compressor in a deep vacuum, internal dam-

age will result.

1. Manifold Gauge Set

2. Hose Fitting (0.5-16 Acme)

3. Refrigeration and/or Evacuation Hose

(SAE J2196/R-134a)

4. Hose Fitting w/O-ring (M14 x 1.5)

5. High Side Field Service Coupling

6. Low Side Field Service Coupling

a. Attach manifold gauge set to the compressor suction

and discharge service valves. Refer to paragraph 6.3.

b. Start the unit and run in the frozen mode (controller

set below --10°C) for 10 to 15 minutes.

Figure 6-4 R-134a Manifold Gauge/Hos e Set

c. Check function code Cd21 (refer to paragraph 3.2.2).

The economizer solenoid valve should be open. If

not, continue to run until the valve opens.

7. Evacuate to 10 inches of vacuum and then charge

with R-134a to a slightly positive pressure of 0.1 kg/

cm@ (1.0 psig).

d. Frontseat the oil return service valve then, frontseat

theliquid lineservicevalve. Placestart-stop switch in

the OFF position when the suction reaches a positive

pressure of 0.1 kg/cm@ (1.0 psig).

8. Front seat both manifold gauge set valves and dis-

connect from cylinder. The gauge set is now ready

for use.

b. Connecting Manifold Gauge/Hose Set

e. Frontseat the economizer service valve and then

frontseat the suction and discharge service valves.

The refrigerant will be trapped between the compres-

sor suction service valve and the liquid line valve.

To connect the manifold gauge/hose set for reading

pressures, do the following:

1. Remove service valve stem cap and check to make

sure it is backseated. Remove access valve cap. (See

Figure 6-1)

f. Before opening up any part of the system, a slight

positive pressure should be indicated on the pressure

T-309

6-2

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6.6 EVACUATION AND DEHYDRATION

6.6.1 General

gauge. If a vacuum is indicated, emit refrigerant by

cracking theliquid linevalvemomentarilyto buildup

a slight positive pressure.

Moisture is the deadly enemy of refrigeration systems.

The presence of moisture in a refrigeration system can

have many undesirable effects. The most common are

copper plating, acid sludge formation, “freezing-up” of

metering devices by free water, and formation of acids,

resulting in metal corrosion.

g. When opening up the refrigerant system, certain parts

may frost. Allow the part to warm to ambient temper-

ature before dismantling. This avoids internal con-

densation which puts moisture in the system.

h. After repairs have been made, be sure to perform a

refrigerant leak check (refer to paragraph 6.5), and

evacuate and dehydrate the low side (refer to para-

graph 6.6).

6.6.2 Preparation

a. Evacuate and dehydrate only after pressure leak test.

(Refer to paragraph 6.5.)

b. Essential tools to properly evacuate and dehydrate

any system include a vacuum pump (8 m³/hr = 5 cfm

volume displacement) and an electronic vacuum

gauge. (The pump is available from Carrier Trans-

icold, P/N 07-00176-11.)

i. Check refrigerant charge (refer to paragraph 6.7).

6.5 REFRIGERANT LEAK CHECKING

WARNING

c. If possible, keep the ambient temperature above

15.6_C (60_F) to speed evaporation of moisture. If

the ambient temperature is lower than 15.6_C

(60_F), ice might form before moisture removal is

complete. Heat lamps oralternatesourcesofheatmay

be used to raise the system temperature.

Never use air for leak testing. It has been

determined that pressurized, air-rich mix-

tures of refrigerants and air can undergo

combustion when exposed to an ignition

source.

d. Additional time may be saved during a complete sys-

tem pump down by replaceing the filter-drier with a

section of copper tubing and the appropriate fittings.

Installation of a new drier may be performed during

the charging procedure.

a. The recommended procedure for finding leaks in a

system is with aR-134aelectronicleak detector. Test-

ing joints with soapsuds is satisfactory only for locat-

ing large leaks.

b. If the system is without refrigerant, charge thesystem

with refrigerant 134a to build up pressure between

2.1 to 3.5 kg/cm@ (30 to 50 psig). To ensure complete

pressurization of the system, refrigerant should be

charged at the compressor suction and economizer

service valves and the liquid line service valve. Also,

the area between the suction modulating valve and

evaporator expansion valve may not be open to these

charging points. Pressure between these components

may be checked at the low side access valve (item 11,

Figure 2-2) or by checking that the suction modulat-

ing valve is more than 10% open at controller func-

tion code Cd01. The suction modulating valve may

beopened by useofthecontrollerfunction codeCd41

valve override control (refer to paragraph 6.19). Re-

move refrigerant cylinder and leak-check all connec-

tions.

NOTE

Only refrigerant 134a should be used to pres-

surize the system. Any other gas or vapor will

contaminate the system, which will require

additional purging and evacuation of the sys-

tem.

1. Liquid Service Valve

2. Receiver or Water

Cooled Condenser

3. Compressor

4. Discharge Service

Valve

6. Suction Service Valve

7. Vacuum Pump

8. Electronic Vacuum

Gauge

9. Manifold Gauge Set

10. Refrigerant Cylinder

5. Economizer Service 11. Reclaimer

Valve

c. If required, remove refrigerant using a refrigerant

recovery system and repair any leaks.

d. Evacuate and dehydrate the unit. (Refer to paragraph

6.6.)

Figure 6-5. Refrigeration Sys tem Service

Connections

e. Charge unit per paragraph 6.7.

6.6.3 Procedure - Complete s ys tem

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a. Remove all refrigerant using a refrigerant recovery

system.

b. The recommended method to evacuate and dehydrate

the system is to connect evacuation hoses at the com-

pressor suction, compressor economizer and liquid

line service valve (see Figure 6-5). Be sure the ser-

vice hoses are suited for evacuation purposes.

c. The area between the suction modulating valve and

evaporator expansion valve may not be open to the

access valves. To ensure evacuation of this area,

check that the suction modulating valve is more than

10% open at controller function code Cd01. If re-

quired, the suction modulating valve may be opened

by use of the controller function code Cd41 valve

override control. If power is not available to open the

valve, the area may be evacuated by connecting an

additional hose at the low side access valve (item 11,

Figure 2-2).

d. Test the evacuation setup for leaks by backseating the

unit service valves and drawing a deep vacuum with

thevacuum pump and gaugevalves open. Shut offthe

pump and check to see if the vacuum holds. Repair

leaks if necessary.

1. Receiver or Water

Cooled Condenser

2. Compressor

3. Discharge Service

Valve

5. Suction Service Valve

6. Vacuum Pump

7. Electronic Vacuum

Gauge

8. Manifold Gauge Set

9. Refrigerant Cylinder

10. Reclaimer

e. Midseat the refrigerant system service valves.

f. Open thevacuum pump and electronic vacuum gauge

valves, if they are not already open. Start the vacuum

pump. Evacuate unit until the electronic vacuum

gauge indicates 2000 microns. Close the electronic

vacuum gauge and vacuum pump valves. Shut offthe

vacuum pump. Wait a few minutes to be sure the vac-

uum holds.

4. Economizer Service

Valve

Figure 6-6. Compres s or Service Connections

6.6.4 Procedure - Partial Sys tem

a. If the refrigerant charge has been removed from the

compressor for service, evacuate only the compressor

by connecting the evacuation set--up at the compres-

sor service valves. (See Figure 6-6.) Follow evacua-

tion procedures of the preceding paragraph except

leave compressor service valves frontseated until

evacuation is completed.

g. Break the vacuum with clean dry refrigerant 134a

gas. Raise system pressure to approximately 0.2 kg/

cm@ (2 psig), monitoring it with the compound

gauge.

h. Remove refrigerant using a refrigerant recovery sys-

tem.

b. If refrigerant charge has been removed from the low

side only, evacuate the low side by connecting the

evacuation set--up at the compressor suction and

economizer service valves and the liquid service

valve except leave the service valves frontseated until

evacuation is completed.

i. Repeat steps f.and g. one time.

j. Remove the copper tubing and change thefilter-drier.

Evacuate unit to 500 microns. Close the electronic

vacuum gauge and vacuum pump valves. Shut offthe

vacuum pump. Wait five minutes to see if vacuum

holds. This procedure checks for residual moisture

and/or leaks.

c. Once evacuation has been completed and the pump

has been isolated, fully backseat the service valves to

isolate the service connections and then continue

with checking and, if required, adding refrigerant in

accordance with normal procedures

k. With a vacuum still in the unit, the refrigerant charge

may be drawn into the system from a refrigerant con-

tainer on weight scales. Continue to paragraph 6.7

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6.7 REFRIGERANT CHARGE

e. Start unit in cooling mode. Run approximately 10

minutes and check the refrigerant charge.

6.7.1 Checking the Refrigerant Charge

6.7.3 Adding Refrigerant to Sys tem (Partial

Charge)

a. Examine the unit refrigerant system for any evidence

of leaks. Repair as necessary. (Refer to paragraph

6.5.)

NOTE

To avoid damage to the earth’s ozone layer, use

a refrigerant recovery system whenever remov-

ing refrigerant. When working with refriger-

ants you must comply with all local govern-

ment environmental laws. In the U.S.A., refer

to EPA section 608.

b. Maintain the conditions outlined in paragraph 6.7.1

c. Fully backseat the suction service valve and remove

the service port cap.

d. Connect charging line between suction service valve

port and cylinder of refrigerant R-134a. Open

VAPOR valve.

a. Connect the gauge manifold to the compressor dis-

chargeand suction service valves. For units operating

on a water cooled condenser, change over to air

cooled operation.

e. Partially frontseat (turn clockwise) the suction ser-

vice valve and slowly add charge until the refrigerant

appears at the properlevel . Be careful not to frontseat

the suction valve fully, if the compressor is operated

in a vacuum internal damage may result.

b. Bring the container temperature to approximately

1.7_C (35_F)or --17.8_C (0_F). Then set thecontrol-

ler set point to --25_C (--13_F) to ensure that the suc-

tion modulation valve is fully open. (Position of the

suction modulating valve may be checked at control-

ler function code Cd01.)

6.8 COMPRESSOR -- Model RSH105

WARNING

Make sure power to the unit is OFF and

power plug disconnected before replacing

the compressor.

c. Partially block the condenser coil inlet air. Increase

the area blocked until the compressor discharge pres-

sure is raised to approximately 12 kg/cm@ (175 psig).

WARNING

d. On units equipped with a receiver, the level should be

between the glasses. On units equipped with a water

cooled condenser, the level should be at the center of

the glass. If the refrigerant level is not correct, contin-

ue with thefollowing paragraphs to add or removere-

frigerant as required.

Before disassembly of the compressor make

sure to relieve the internal pressure very

carefully by slightly loosening the couplings

to break the seal.

6.7.2 Adding Refrigerant to Sys tem (Full Charge)

CAUTION

The scroll compressor achieves low suction

pressure very quickly. Do not use the com-

pressor to evacuate the system below zero

psig. Never operate the compressor with the

suction or discharge service valves closed

(frontseated). Internal damage will result

from operating the compressor in a deep

vacuum.

a. Evacuate unit and leave in deep vacuum. (Refer to

paragraph 6.6.)

b. Place cylinder of R-134a on scale and connect charg-

ing line from cylinder to liquid line valve. Purge

charging line at liquid linevalve and then noteweight

of cylinder and refrigerant.

c. Open liquid valve on cylinder. Open liquid line valve

half-way and allow the liquid refrigerant to flow into

the unit until the correct weight ofrefrigerant (referto

paragraph 2.2) has been added as indicated by scales.

6.8.1 Removal and Replacement of Compres s or

NOTE

Service compressor contains a nitrogen charge.

Due to the hygroscopic nature of the oil, time

the compressor is left open to the atmosphere

should be minimized as much as possible.

NOTE

It may be necessary to finish charging unit

through suction service valve in gas form, due

to pressure rise in high side of the system.

(Refer to section paragraph 6.7.3)

a. Procure a replacement compressor kit. A list of items

contained in the compressor kit is provided in

Table 6-1.

d. Backseat manual liquid line valve (to close off gauge

port). Close liquid valve on cylinder.

b. If the compressor is operational, pump the unit down

(refer to paragraph 6.4).

T-309

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Table 6-1 Compres s or Kit

Component

Compressor

Service Valve Seal

Mylar Washers

Item

Qty

SST Washer

(Kit Item 10)

Resilient Mount

(Kit Item 6)

Wire Tie

Oil Sight Glass Plug

Resilient Mount

Upper Shock Mount Ring

Upper Shock Mount Bushing

Compressor Power Plug O--Ring

SST Washer

(Kit Item 10)

Mylar Washer

(Kit Item 3)

10 SST Washers

Mylar Protector

(Retain)

c. If the compressor is not operational, turn the unit

start--stop switch (ST) and unit circuit breaker

(CB--1) OFF. Disconnect power to theunit and front--

seat thedischarge, suction, economizer, and oil return

service valves.

Base Plate

(Retain)

Mylar Protector

(Retain)

Remove all remaining refrigerant from the compres-

sor using a refrigerant recovery system. Connect

hoses to suction, economizer and discharge service

valves ports. Evacuate compressor to 500 microns

(75.9 cm Hg vacuum = 29.9 inches Hg vacuum).

Figure 6-8 Compres s or Lower Mounting

d. Make sure power to the unit is OFF and unit power

plug disconnected. Disconnect the power plug from

the compressor.

g. Replace the upper mounting bracket shock mount

ring and bushing (kit items 7and 8). Reassemble the

bracket in the same manner as the original and torque

the shoulder bolt to 2.8 mkg (20 ft--lbs.).

e. Loosen and break the seal at fittings from the suction,

discharge, economizer, and the oil return service

valves. Remove fittings and discard service valve

seals, retain oil return valve O--ring.

h. Remove the male coupling from the top of the sight

glass on the old compressor and hand assemble to the

oil return valve coupling for safe keeping. Plug the

top of the replacement compressor sight glass with

the plug (kit item 5) to prevent spilling oil.

f. Remove the entire compressor upper mounting

bracket assembly,(see Figure 6-7) by removing the

fourcap screws attaching it to theunit and the32--mm

bolt from the compressor mounting bracket.

i. Remove the lower mounting bolts and hardware (see

Figure 6-8). Using plugs from replacement compres-

sor, plug connections on old compressor. Removethe

old compressor. Refer to paragraph 2.2for compres-

sor weight. Return plugs to replacement compressor.

j. The replacement compressor is shipped with an oil

charge of 591ml (20 ounces). Before sliding the new

compressorin theunit, removetheoil sight glassplug

and (using a small funnel) charge the compressor

with an additional 1893ml (64 ounces) Castrol--Ice-

maticSW20 (POEoil). Reassembletheoil sightglass

plug to avoid spilling oil when sliding thecompressor

in the unit.

Upper Shock Mount

Bushing(Kit Item 8)

Ring (Kit Item 7)

32mm Bolt

k. Secure the base plate and mylar protectors to the com-

pressor with wire ties (kit item 4), and place the com-

pressor in the unit.

Shoulder Bolt

l. Cut and remove the wire ties that were used to hold

the base plate and protectors to the compressor. Us-

ing new resilient mounts, SST washers and mylar

washers (kit items 3, 6 & 10). Install the four mount-

ing screws loosely.

m.Install themalecoupling (removed in step h.) into the

sight glass port.

Figure 6-7 Compres s or Upper Mounting

T-309

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n. Place the new service seals (kit item 2) at the com-

pressor service ports, connect the four service valves

loosely.

5 Turn Start/Stop switch off and allow oil to drain into

compressor sump. Oil level must be visible in the

sight glass. Ifit is not visible, oil must beadded tothe

compressor.

o. Torquethe fourresilient mount screws to 6.2 mkg (45

ft--lbs).

b. Adding Oil with Compres s or in Sys tem

1. The recommended method is to add oil using an oil

pump at the oil return service valve (see item 15,

Figure 2-3)

p. Torque the four service valves to:

Service Valve

Torque

Suction or Discharge

11 to 13.8 mkg

(80 to 100 ft--lbs.)

2. In an emergency where an oil pump is not available,

oil may bedrawn into the compressorthrough theoil

return service valve.

Economizer

Oil Return

6.9 to 8.3 mkg

(50 to 60 ft--lbs.)

1.4 to 1.66 mkg

(10 to 12 ft--lbs.)

Connect the suction connection of the gauge man-

ifold to the compressor oil return valve port, and

immerse the common connection of the gauge man-

ifold in an open container of refrigeration oil.

Extreme care must be taken to ensure the manifold

common connection remains immersed in oil at all

times. Otherwise air and moisture will be drawn into

the compressor. Crack the oil return service valve

and gaugevalveto vent asmall amount ofrefrigerant

through the common connection and the oil to purge

the lines of air. Close the gauge manifold valve.

q. Reassemble the top mounting bracket (see

Figure 6-7) by hand tightening the 32--mm (1¼

--inch) bolt and torquing the four mounting screws to

0.9 mkg (6.5 ft--lbs). Align the mounting so that the

ring and bushing assembly are free with no compres-

sion.

r. Torque the 32mm bolt to 1.5 mkg (11 ft--lbs.). While

maintaining the free movement of the shock mount,

torque the four mounting screws to 0.9 mkg (6.5 ft--

lbs.).

With the unit running, turn the suction service valve

toward frontseat and induce a vacuum in the com-

pressor crankcase. Do not allow the compressor to

pull below 127mm/hg (5 “/hg). SLOWLY crack the

suction gauge manifold valve and oil will flow

through theoil return servicevalveinto thecompres-

sor. Add oil as necessary.

s. Replace the power plug O--Ring with new ring (kit

item 9). Insert the power plug into the compressor fit-

ting. Be sure plug is fully seated into the fitting and

then thread the coupling nut a minimum of 5 turns.

t. Leak check and evacuate the compressor to 1000 mi-

3 Run unit for 20 minutes in cooling mode. Check oil

level at the compressor sight glass.

crons. Refer to paragraphs 6.5 and 6.6

u. Run the unit for at least 15 minutes and check the oil

and refrigerant levels. Refer to paragraphs 6.7 and

6.9.

c. Removing Oil from the Compres s or:

1 If the oil level is above the sight glass, oil must be

removed from the compressor.

2 Perform a compressor pump down, refer to section

6.4.

6.9 COMPRESSOR OIL LEVEL

3 Removetheoil plug, and drain oil until alevel can be

seen in the sight glass.

CAUTION

Use only Carrier Transicold approved

Polyol Ester Oil (POE) -- Mobil ST32 com-

pressor oil with R-134a. Buy in quantities of

onequart or smaller. When using this hygro-

scopic oil, immediately reseal. Do not leave

container of oil open or contamination will

occur.

4 Run unit for 20 minutes in cooling mode. Check oil

level at the compressor sight glass.

6.10 HIGH PRESSURE SWITCH

6.10.1 Replacing High Pres s ure Switch

a. Turn unit start-stop switch OFF. Frontseat the suc-

tion, discharge, economizer and oil return service

valves to isolate compressor. Remove the refrigerant

from the compressor.

a. Checking the Oil Level in the Compres s or

1 Ideally, ambient temperature should be between

40_F and 100_F.

b. Disconnect wiring from defective switch. The high

pressure switch is located on the discharge service

valve and is removed by turning counterclockwise.

(See Figure 2-3.)

2 Operate the unit in cooling mode for at least 20 min-

utes.

3 Check the controller function code Cd1 for the suc-

tion modulation valve (SMV) position. It should be

at least 20% open.

c. Install a new high pressure switch after verifying

switch settings. (Refer to paragraph 6.10.2.)

4 Locate the oil sight glass on the side of the compres-

sor (item 7, Figure 2-3).

d. Evacuate and dehydrate the compressor per para-

graph 6.6.

T-309

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6.10.2 Checking High Pres s ure Switch

c. Unsolder discharge line and remove the line to the

receiver or water-cooled condenser.

WARNING

d. Remove coil mounting hardware and remove the

coil.

Do not use a nitrogen cylinder without a

pressure regulator. Do not use oxygen in or

near a refrigeration system as an explosion

may occur.

e. Install replacement coil and solder connections.

f. Leak-check the coil connections per paragraph para-

graph 6.5. Evacuate the unit per paragraph 6.6 then

charge the unit with refrigerant per paragraph 6.7.

NOTE

The high pressure switch is non-adjustable.

6.12 CONDENSER FAN AND MOTOR ASSEMBLY

a. Remove switch as outlined in paragraph 6.10.1

WARNING

Do not open condenser fan grille before

turning power OFF and disconnecting

power plug.

b. Connect ohmmeter or continuity light across switch

terminals. Ohm meter will indicate no resistance or

continuity light will be illuminated if the switch

closed after relieving compressor pressure.

The condenser fan rotates counter-clockwise (viewed

from front of unit), pulls air through the the condenser

coil, and discharges horizontally through thefront ofthe

unit. To replace motor assembly:

c. Connect hose to a cylinder of dry nitrogen. (See

Figure 6-9.)

a. Open condenser fan screen guard.

1. Cylinder Valve

b. Loosen two square head set screws on fan. (Thread

sealer has been applied to set screws at installation.)

Disconnect wiring from motor junction box.

and Gauge

2. Pressure Regulator

3. Nitrogen Cylinder

4. Pressure Gauge

(0 to 36 kg/cm@ =

0 to 400 psig)

CAUTION

Take necessary steps (place plywood over

coil or use sling on motor) to prevent motor

from falling into condenser coil.

5. Bleed-Off Valve

6. 1/4 inch Connection

c. Remove motor mounting hardware and replace the

motor. It is recommended that new locknuts be used

when replacing motor. Connect wiring per wiring

diagram.

Figure 6-9 High Pres s ure Switch Tes ting

d. Set nitrogen pressure regulator at 26.4 kg/cm@ (375

psig) with bleed-off valve closed.

d. Install fan loosely on motor shaft (hub side in). DO

NOTUSEFORCE. If necessary, tap thehub only, not

the hub nuts or bolts. Install venturi. Apply “Loctite

H” to fan set screws. Adjust fan within venturi so that

the outer edge of the fan is within 2.0 ± .07 mm

(0.08” ¦ 0.03”) from the outside of the orifice open-

ing. Spin fan by hand to check clearance.

e. Close valve on cylinder and open bleed-off valve.

f. Open cylinder valve. Slowly close bleed-off valve to

increase pressure on switch. The switch should open

at a static pressure up to 25 kg/cm@ (350 psig). If a

light is used, light will go out. If an ohmmeter is used,

the meter will indicate open circuit.

e. Close and secure condenser fan screen guard.

g. Slowly open bleed-off valve to decrease the pressure.

The switch should close at 18 kg/cm@ (250 psig).

f. Apply power to unit and check fan rotation. If fan

motor rotates backward, reverse wire numbers 5 and

6.11 CONDENSER COIL

The condenser consists of a series of parallel copper

tubes expanded into copper fins. The condenser coil

must becleaned with fresh water orsteam so the airflow

is not restricted. To replace the coil, do the following:

6.13 FILTER-DRIER

On units equipped with a water-cooled condenser, if the

sight glass appears to be flashing or bubbles are

constantly moving through the sight glass when the

suction modulation valve is fully open, the unit may

have a low refrigerant charge or the filter-drier could be

partially plugged.

WARNING

Do not open the condenser fan grille before

turning power OFF and disconnecting

power plug.

a. To Check Filter-Drier

1. Test for a restricted or plugged filter-drier by feeling

the liquid line inlet and outlet connections of the

drier cartridge. If the outlet side feels cooler than the

inlet side, then the filter-drier should be changed.

a. Using a refrigerant reclaim system, remove the

refrigerant charge.

b. Remove the condenser coil guard.

T-309

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2. Check the moisture-liquid indicator if the indicator

shows ahigh level ofmoisture, thefilter-driershould

be replaced.

a. Open the heater access panel (see Figure 2-1) to ex-

pose the evaporator expansion valve.

b. Attach a temperature sensor near the expansion valve

bulb and insulate. Make sure the suction line is clean

and that firm contact is made with the sensor.

b. To Replace Filter-Drier

1. Pump down the unit (refer to paragraph 6.4 and

replace filter-drier.

c. Connect an accurate gauge to the service port directly

upstream of the suction modulating valve.

2. Evacuate the low side in accordance with paragraph

6.6.

d. Set the temperature set point to --18_C (0_F), and run

unit until conditions stabilize.

3. Afterunit is in operation, inspect formoisture in sys-

tem and check charge.

e. The readings may cycle from a high to a low reading.

Take readings of temperature and pressure every

three to five minutes for a total of 5or 6 readings

6.14 EXPANSION VALVES

f. From the temperature/pressure chart (Table 6-7), de-

termine the saturation temperature corresponding to

the evaporator outlet test pressures at the suction

modulation valve.

Two expansion valves are used, the evaporator

expansion valve (item 9, Figure 2-2), and the

economizer expansion valve (item 26, Figure 2-4) .The

expansion valves are automatic devices which maintain

constant superheat of the refrigerant gas leaving at the

point of bulb attachment regardless of suction pressure.

g. Subtract the saturation temperatures determined in

step f. from the temperatures measured in step e.. The

difference is the superheat of the suction gas. Deter-

mine the average superheat It should be 4.5 to 6.7 °C

(8 to 12 °F)

The valve functions are:

1. Automatic control of the refrigerant flow to match

the load.

6.14.2 Valve Replacement

2. Prevention of liquid refrigerant entering the com-

pressor.

a. Removing the Expansion Valve

Unless the valve is defective, it seldom requires

maintenance other than periodic inspection to ensure

that thethermal bulb is tightly secured tothesuctionline

and wrapped with insulating compound. (See

Figure 6-10.)

NOTES

1. The TXV’s are hermetic valves and do not

have adjustable superheat.

2. All connections on the evaporator TXV are

bi---metallic, copper on the inside and

stainless on the outside. When brazing,

bi---metallic connections heat up very

quickly.

1. Suction Line

2. TXV Bulb Clamp

3. Nut and Bolt

4. TXV Bulb

Figure 6-10 Thermostatic Expansion Valve Bulb

6.14.1 Checking Superheat.

1. Evaporator Expansion Valve

2. Non-adjustable Superheat Stem

3. Equalizer Connection

4. Inlet Connection

NOTE

Proper superheat measurement for the evapora-

tor expansion valve should be completed at

-- 1 8 _C (0_F) container box temperature where

possible. If the economizer valve is suspect, it

should be replaced.

5. Outlet Connection

6. Expansion Valve Bulb

Figure 6-11 Evaporator Expans ion Valve

T-309

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Braze Rod

(’Sil-Phos” = 5.5% Silver, 6% Phosphorus)

Copper Tube

(Apply heat for

10-15 seconds)

Bi-metallic Tube Connection

(Apply heat for 2-5 seconds)

Use of a wet cloth is not neces-

sary due to rapid heat dissipation

of the bi--metallic connections

Figure 6-12 Hermetic Thermostatic Expans ion Valve Brazing Procedure

7. If applicable, braze the equalizer connection to the

equalizer line.

8. Check superheat (refer to step 6.14.1).

6.15 EVAPORATOR COIL AND HEATER

ASSEMBLY

INLET

The evaporator section, including the coil, should be

cleaned regularly. The preferred cleaning fluid is fresh

waterorsteam. Anotherrecommended cleaneris Oakite

202 or similar, following manufacturer’s instructions.

OUTLET

The two drain pan hoses are routed behind the

condenser fan motor and compressor. The drain pan

line(s) must be open to ensure adequate drainage.

Figure 6-13 Economizer Expans ion Valve

6.15.1 Evaporator Coil Replacement

1. Pump down the unit per paragraph 6.4.

a. Pump unit down. (Refer to paragraph 6.4.)

2. Removecushion clamps located on theinlet and out-

let lines.

b. With power OFF and power plug removed, remove

the screws securing the panel covering the evaporator

section (upper panel).

3. Unbraze the equalizer connection (if applicable), the

outlet connection and then the inlet connection.

c. Disconnect the defrost heater wiring.

d. Disconnect the defrost temperature sensor (see Fig-

ure Figure 2-2 from the coil. .

4. Remove insulation (Presstite) from expansion valve

bulb.

e. Remove middle coil support.

5. Unstrap thebulb, located belowthecenterof thesuc-

tion line (4 o’clock position), and remove the valve.

f. Remove the mounting hardware from the coil.

g. Unsolder the two coil connections, one at the distrib-

utor and the other at the coil header.

b. Installing the Expansion Valve

1. Clean the suction line with sandpaper before instal-

ling bulb to ensure proper heat transfer. Apply ther-

mal grease to the indentation in the suction line.

h. After defective coil is removed from unit, remove

defrost heaters and install on replacement coil.

i. Install coil assembly by reversing above steps.

2. Strap the thermal bulb to the suction line, making

sure bulb is placed firmly into the suction line. See

Figure 6-10 for bulb placement.

j. Leak check connections per paragraph 6.5. Evacuate

the unit per paragraph 6.6 and add refrigerant charge

per paragraph 6.7.

3. Insulate the thermal bulb.

6.15.2 Evaporator Heater Replacement

a.Beforeservicing unit, makesuretheunit circuit break-

ers (CB-1 & CB-2) and the start-stop switch (ST) are

in theOFF position, and that thepowerplug andcable

are disconnected.

4. The economizer expansion valves should be

wrapped in a soaked cloth for brazing. See

Figure 6-12. Braze inlet connection to inlet line

5. Braze outlet connection to outlet line.

b. Remove the lower access panel (Figure 2-1) by

removing the T.I.R. locking device lockwire and

mounting screws.

6. Reinstall the cushion clamps on inlet and outlet

lines.

T-309

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c. Determine which heater(s) need replacing by check-

ing resistance on each heater. Refer to paragraph 2.3

for heater resistance values

2 Be sure electrical power is removed from the unit.

Disconnect leads. Remove top screw and washer.

Lift off coil. (See Figure 6-14 or Figure 6-15)

3 Unbraze valve from unit and braze new valve in

place

d. Remove hold-down clamp securing heaters to coil.

e. Lift the bent end of the heater (with the opposite end

down and away from coil). Move heater to the side

enough to clear the heater end support and remove.

4 Install coil. Evacuate low side and place unit back

in operation. Check charge.

6.16 ECONOMIZER, UNLOADER, LIQUID INJ EC-

TION AND OIL RETURN SOLENOID VALVE

a. Replacing the Coil

NOTE

The coil may be replaced without removing the

refrigerant.

1 Be sure electrical power is removed from the unit.

Disconnect leads. Remove top screw and washer.

Lift off coil. (See Figure 6-14 or Figure 6-15)

2 Verify coil type, voltage and frequency of old and

new coil. This information appears on the coil hous-

ing.

b. Replacing Valve Internal Parts (Unloader

Solenoid Only)

1 Pump down the unit. Refer to paragraph 6.4.

1. Top Screw

2. Washer

3. Coil

6. Gasket

2 Be sure electrical power is removed from the unit.

Disconnect leads. Remove top screw and washer.

Lift off coil. (See Figure 6-14)

7. Stem and Plunger

8. Seat Disc

9. Body

4. Locknut

5. Enclosing Tube

3 Remove the top screw (see Figure 6-14), washer ,

and coil assembly.

Figure 6-14. Unloader Solenoid Valve

4 Loosen the enclosing tube locknut.

5 Remove enclosing tube and locknut assembly. The

gasket is inside the enclosing tube.

6 Remove seat disc from inside of body and check for

obstructions and foreign material.

7 Placetheseat discinto thevalvebodywith thesmall-

er diameter end facing up.

8 Install stem and plunger.

9 Place the enclosing tube locknut over the enclosing

tube. Install spacer over enclosing tube making sure

it is seated properly in the enclosing tube locknut.

Tighten enclosing tube locknut to a torque value of

2.78 mkg (20 ft-lb). Do not overtighten.

1. Slotted Screw

2. Washer

3. Coil

4. Enclosing Tube and

Body

10 Install coil assembly, washer and top screw.

11 Evacuateand dehydratethesystem. (Referto section

6.6.) Charge unit with refrigerant per section 6.7.

Figure 6-15. Oil Return Solenoid Valve (ORV),

Economizer Solenoid Valve (ESV), Liquid

Injection Solenoid Valve (LIV)

12 Start unit and check operation.

c. Replacing Valve

6.17 EVAPORATOR FAN AND MOTOR ASSEMBLY

1 To replace the unloader, liquid injection or econo-

mizervalve, pump down the unit. Refer to paragraph

6.4. To replace the oil return valve, remove the re-

frigerant charge.

The evaporator fans circulate air throughout the

container by pulling air in the top of the unit. The air is

forced through the evaporator coil where it is either

heated or cooled and then discharged out the bottom of

T-309

6-11

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6.18 EVAPORATOR FAN MOTOR CAPACITORS

the refrigeration unit into the container. The fan motor

bearings are factory lubricated and do not require

additional grease.

The evaporator fan motors are of the permanent-split

capacitor type. The motor is equipped with one

capacitor used in the high speed circuit and another

capacitor used for the low speed circuit.

6.17.1 Replacing The Evaporator Fan As s embly

WARNING

6.18.1 When To Check For A Defective Capacitor

Always turn OFF the unit circuit breakers

(CB-1 & CB-2) and disconnect main power

supply before working on moving parts.

a. Fan motor will not change speed. For example: in the

conventional perishable mode, the motors should run

in high speed. In the economy perishable mode they

should switch speeds and in the frozen mode, the mo-

tors should run in low speed.

a. Remove upper access panel (see Figure 2-2) by

removing mounting bolts and T.I.R. locking device.

Reach inside of unit and remove the Ty-Rap securing

the wire harness loop. Then unplug the connector by

twisting to unlock and pulling to separate. NOTE: It

may be easier to unplug the connector with the motor

assembly partially pulled out (after step b).

NOTE

The evaporator fan motors will always start in

high speed.

b. Motor running in wrong direction (after checking

for correct wiring application).

b. Remove the four mounting bolts that secure the mo-

tor--fan assembly to the unit.

c. Motor will not start, and IP-EM’s are not open.

c. Slide the fan assembly out from the unit and place it

on a sturdy work surface.

6.18.2 Removing The Capacitor

WARNING

d. Remove the motor and fan from the assembly.

e. Replace the motor.

Make sure power to the unit is OFF and

power plug disconnected before removing

capacitor(s).

f. Lubricate the fan motor shaft with a graphite--oil

solution (Never--Seez) and apply thread sealer (Loc-

tite H, brown in color) to the two fan set screws.

Install fan on themotorshaft, so that the coupling sur-

face will be even with the end of the motor shaft.

The capacitors are located on the motor and above the

evaporator fan deck they may be removed by two

methods:

1 If container is empty, open upper rear panel of the

unit. The capacitor may be serviced after disconnect-

ing power plug.

g. Install the fan assembly in reverse order of removal.

Apply power momentarily to check for proper fan

rotation (refer to paragraph 2.3). If thefan spins back-

wards, than motor wiring or motor is defective.

2 If container is full, turn the unit power OFF and dis-

connect power plug. Remove the evaporator fan

motor access panel. (See see Figure 2-1). For

removal of the evaporator fan assembly, refer to sec-

tion 6.17.

Replace access panel making sure that panel does not

leak. Lock--wire the T.I.R. locking device(s).

WARNING

With power OFF dischargethe capacitor be-

fore disconnecting the circuit wiring.

6.18.3 Checking The Capacitor

If the capacitor is suspected of malfunction, you may

choose to simply replace it. Direct replacement requires

a capacitor of the same value. Two methods for

checking capacitor function are:

1. Volt-ohmmeter set on RX 10,000 ohms.

Connect ohmmeter leads across the capacitor terminals

and observe the meter needle. If the capacitor is good,

the needle will make a rapid swing toward zero

resistance and then gradually swing back toward a very

high resistance reading.

If the capacitor has failed open, the ohmmeter needle

will not move when the meter probes touch the

terminals. If the capacitor is shorted, the needle will

swing to zero resistance position and stay there.

1. Bracket

6. Cap Screw, Hxhd

5/16-18 x 1.25

7. Fan

8. Shim

9. Evaporator Motor

2. Flat washer, 3/8

3. Bolt, 3/8-16 x 1.00

4. Locknut, 5/16-18

5. Flat washer, 5/16

2. Capacitor analyzer:

The function of the analyzer is to read the microfarad

value of a capacitor and to detect insulation breakdown

Figure 6-16. Evaporator Fan As s embly

T-309

6-12

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under load conditions. The important advantages of a

analyzer are its ability to locate capacitors that have

failed to hold their microfarad ratings, or those that are

breaking down internally during operation. It is also

useful in identifying capacitors when their microfarad

rating marks have become unreadable.

Right Dis play

CAP

(Capacity Mode)

Available Selections

AUtO

(Normal Control)

UnLd

(Unloader = Open

Economizer = Closed)

6.19 VALVE OVERRIDE CONTROLS

Std

(Unloader = closed

Economizer = closed)

CAUTION

ECOn

DO NOT disassemblepiston from NEW suc-

tion modulating valve powerhead assembly.

Doing so may result in damage to piston.

(Unloader = closed

Economizer = open)

AUtO

(SMV % Setting)

(Normal Control)

Controller function code Cd41 is a configurable code

that allows timed operation of the automatic valves for

troubleshooting. Threetest sequences are provided. The

first, capacity mode (CAP), allows alignment of the

unloader and economizer solenoid valves in the

standard, unloaded and economized operating

configurations. The second, SMV % Setting (SM)

allows opening of the suction modulating valve to

various percentages and the third, Oil Valve Setting

(OIL)and Liquid ValveSetting (LIV)allows opening or

closing of the oil return solenoid valve and the liquid

injection solenoid valve. A fourth selection is also

provided to enter a time period of up to three minutes,

during which the override(s) are active. If the timer is

active, valve override selections will take place

immediately. If the timer is not active, changes will not

take place for a few seconds after the timer is started.

When the timer times out, override function is

automatically terminated and the valves return to

normal machinery control. To operate the override, do

the following:

100

AUto

(Normal Control)

OPEn

AUto

(Normal Control)

OIL

(Oil Valve Setting)

LIV

(Liquid Valve Setting, if

applicable)

OPEn

0 00 (0 minutes/0 Seconds)

In 30 second increments to

3 00 (3 minutes/ 0 seconds)

tIM

(Timer)

6.20 SUCTION MODULATION VALVE

a. Press theCODE SELECT key then press anARROW

key until Cd41 is displayed in the left window. The

right window will display a controller communica-

tions code.

On start up of the unit, the valve will reset to a known

open position. This is accomplished by assuming the

valve was fully open, driving it fully closed, resetting

the percentage open to zero, then opening to a known

10% staging position.

b. Press the ENTER key. The left display will show a

test name alternating with the test setting or time re-

maining. Use an ARROW key to scroll to the desired

test. Press the ENTER key and SELCt will appear in

the left display.

FROM COIL

2-1/8 inch Nut

c. Use an ARROW key to scroll to the desired setting,

and then press the ENTER key. Selections available

for each of the tests are provided in the following

table.

d. If the timer is not operating, follow the above proce-

dure to display the timer. Use an ARROW key to

scroll to thedesired timeinterval and press ENTER to

start the timer.

TO COMPRESSOR

FROM UNLOADER

e. The above described sequence may be repeated dur-

ing the timer cycle to change to another override.

Figure 6-17 Suction Modulation Valve (SMV)

T-309

6-13

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6.20.1 Precheck Procedure

ing to light indicates an open on that leg which indi-

cates a poor connection or an open coil. Repair or re-

place as required to achieve proper operation.

a. Check unit for abnormal operation.

b. Check charge. If refrigerant is low repair as required

and again check operation.

CAUTION

c. If sufficient capacity cannot be maintained or unit is

tripping excessively on high pressure switch (HPS)

in high ambients, check coils and clean if required.

The scroll compressor achieves low suction

pressure very quickly. Do not operate the

compressor in a deep vacuum, internal dam-

age will result.

d. If capacity or control cannot be maintained turn unit

OFF, then back ON. This will reset the valve in the

event the controller lost communication with the

valve, and may correct the problem.

3. Restart unit, set the step rate to 200 PPS on SMA-12

forthevalve, and close steppervalve whilewatching

the suction gauge. Within one minute the suction

pressure will go into a vacuum. This is an indication

that the valve is moving.

NOTE

Carefully listen to the valve. During reset, the

valve will make a ratcheting noise that may be

heard or felt as it is attempting to close. If this

can be heard or felt, it indicates that the control-

ler and drive module are attempting to close the

valve, and may serve as a quick indication that

the drive is in working order.

4. If no change in suction pressure is detected, check

for resistance (refer to step 6.20.2), and check con-

nections for proper continuity and retest. If the valve

is functioning and all connections and motor resist-

ance are good, check the controller and expansion

module.

CAUTION

DO NOT disassemblepiston from NEW suc-

tion modulating valve powerhead assembly.

Doing so may result in damage to piston.

e. Operation of the valve may be checked using the con-

troller valve override program, function code Cd41.

Refer to paragraph 6.19 for valve override test in-

structions.

5. If the valve is determined as faulty after completing

the above steps, perform a low side pump down. Re-

move valve powerhead assembly, and replace with a

NEWvalvepowerhead assembly, torquenut to 35 ft-

lb, evacuate low side, and open all service valves.

6.20.2 Checking The Stepper valve

a. Checking with ohmmeter

Disconnect the four pin connector to the stepper SMV.

With a reliable digital ohmmeter, check the winding

resistance. In normal ambient, the valve should have 72

to 84 ohms measured on the red/green (a-b terminals)

and on the white/black (c-d terminals) leads. If an

infinite or zero reading occurs, check connections and

replace the motor.

6.21 CONTROLLER AND EXPANSION MODULE

6.21.1 Handling Modules

CAUTION

Do not remove wire harnesses from module

unless you are grounded to the unit frame

with a static safe wrist strap.

b. Checking with SMA-12 portable stepper drive tester

The SMA-12 portable stepper drive tester (Carrier

Transicold P/N 07-00375-00) is a battery operated

stepperdrive which will open and closethe SMV, which

allows a more thorough check of the operating

mechanism.

CAUTION

Unplug all module connectors before per-

forming arc welding on any part of the con-

tainer.

To check operation:

1. Stop theunit, disconnect the fourpin connectorfrom

thesteppermoduleto thevalve(seeFigure 6-17)and

attach theSMA-12 stepperdriveto theconnectorgo-

ing to the valve.

The guidelines and cautions provided herein should be

followed when handling the modules. These

precautions and procedures should be implemented

when replacing a module, when doing any arc welding

on the unit, or when service to the refrigeration unit

requires handling and removal of a module.

2. Set the SMA-12 pulse per second (PPS) to one PPS

and either open or close valve. Each LED should

light sequentially until all four are lit. Any LED fail-

T-309

6-14

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This test point enables the user to check if the controller

unloader solenoid valve relay (TU) is open or closed.

TP2

This test point enables the user to check if the high

pressure switch (HPS) is open or closed.

TP3

This test point enables the user to check if the water

pressure switch (WP) contact is open or closed.

TP 4

This test point enables the user to check if the internal

protectorforthecondenserfan motor(IP-CM)is open or

closed.

TP 5

This test point enables the user to check if the internal

protectors for the evaporator fan motors (IP-EM1 or

IP-EM2) are open or closed.

TP 6

This test point is not used in this application.

TP 7

This test point enables the user to check if the controller

economizer solenoid valve relay (TS) is open or closed

1. Controller Software

Programming Port

2. Mounting Screw

3. Controller

4. Expansion Module

5. Test Points

TP 8

This test point enables the user to check power to the

suction modulator valve.

TP 9

Figure 6-18 Controller Section of the Control Box

This test point is the chassis (unit frame) ground

connection.

a. Obtain a grounding wrist strap (Carrier Transicold

part number 07--00--304--00)and a static dissipation

mat (Carrier Transicold part number 07--00304--00.

The wrist strap, when properly grounded, will dissi-

pate any potential buildup on the body. The dissipa-

tion mat will provide a static-free work surface on

which to place and/or service the modules.

TP 10

This test point enables the user to check if the heat

termination thermostat (HTT) contact is open or closed.

6.21.3 Controller Programming Procedure

To load newsoftwareinto themodule, theprogramming

card is inserted into the programming/software port.

b. Disconnect and secure power to the unit.

c. Place strap on wrist and attach the ground end to any

exposed unpainted metal area on the refrigeration

unit frame (bolts, screws, etc.).

CAUTION

The unit must be OFF whenever a program-

ming card is inserted or removed from the

controller programming port.

d. Carefully removethemodule. Do not touch any ofthe

electrical connections if possible. Place the module

on the static mat.

NOTE

e. The strap should be worn during any service work on

a module, even when it is placed on the mat.

The metal door on the programming card must

be facing to the left when inserting.

6.21.2 Controller Trouble-Shooting

a. Procedure for loading Operational Software

1. Turn unit OFF, via start-stop switch (ST).

Agroup oftest points (TP, seeFigure 6-18)areprovided

on the controller for trouble-shooting electrical circuits

(see schematic diagram, section 7). A description of the

test points follows:

2. Insert the programming card for Operational Soft-

ware into the programming/software port. (See

Figure 6-18)

NOTE

3. Turn unit ON, via start-stop switch (ST).

Use a digital voltmeter to measure ac voltage

between TP’s and ground (TP9), except for

TP8.

4. The Display module will alternate back and forth

between the messages “rEV XXXX” and “Press

EntR”. (If a defective card is being used the Display

will blink the message “bAd CArd”. Turn start-stop

switch OFF and remove the card.)

TP1

T-309

6-15

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5. Press the ENTER key on the keypad.

3 Disconnect theback connectors and removemodule.

4 When removing the replacement module from its

packaging , note how it is packaged. When returning

the old module for service, place it in the packaging

in the same manner as the replacement. The packag-

ing has been designed to protect the module from

both physical and electrostatic discharge damage

during storage and transit.

6. The Display will showthe message“Pro SoFt.”This

message will last for up to one minute.

7. The Display module will read “Pro donE” when the

software loading has loaded. (If a problem occurs

while loading the software: the Display will blink

the message “Pro FAIL” or “bad 12V”. Turn start-

stop switch OFF and remove the card.)

b.Installation:

8. Turn unit OFF, via start-stop switch (ST).

Install the module by reversing the removal steps.

9. Remove the programming card from the program-

ming/software port and return the unit to normal op-

eration by placing the start-stop switch in the ON

position.

Torque values for mounting screws (item 2, see

Figure 6-18) are 0.23 mkg (20 inch-pounds). Torque

value for the connectors is 0.12 mkg (10 inch-pounds).

6.22 TEMPERATURE SENSOR SERVICE

b. Procedure for loading Configuration Software

1. Turn unit OFF using start-stop switch (ST).

Procedures for service of the Return Recorder, Return

Temperature, Supply Recorder, Supply Temperature,

Ambient, Defrost Temperature, Compressor Discharge

and Compressor Suction temperature sensors are

provided in the following sub paragraphs.

2. Insert the programming card, for Configuration

Software, into the programming/software port. (See

Figure 6-18.)

3. Turn unit ON using start-stop switch (ST).

6.22.1 Sens or Checkout Procedure

4. The Display module will show “nt40” on the left

LCD display and “531###” on the right LCD dis-

play. “###” will indicate the dash number for agiven

unit model number, use the UP or DOWN ARROW

key to scroll through the list to obtain the proper

model dash number. For example, to program a

model number 69NT40-531-05, press the UP or

DOWN ARROW key until the right display shows

“nt40” on the right display and “53105” on the left.

(If a defective card is being used, the Display will

blink the message “bAd CArd”. Turn start-stop

switch OFF and remove the card.)

Mounting Stud Type

40 mm (1 1/2 inch)

Sens or

6.3 mm (1/4 inch)

Bulb Type

40 mm (1-1/2 inches )

Sens or

6.3 mm (1/4 inch)

40 mm (1-1/2 inches )

Dual Sens or

5. Press the ENTER key on the keypad.

6. When the software loading has successfully com-

pleted, the Display will show the message “EEPrM

donE.” (If a problem occurs while loading the soft-

ware, theDisplay will blink themessage “Pro FAIL”

or “bad 12V.” Turn start-stop switch OFF and

remove the card.)

6.3 mm (1/4 inch)

Figure 6-19 Sens or Types

To check a sensor reading, do the following:

a. Remove the sensor and place in a 0_C (32_F) ice-wa-

ter bath. The ice-water bath is prepared by filling an

insulated container (of sufficient size to completely

immersebulb)with icecubes or chipped ice, then fill-

ing voids between ice with water and agitating until

mixture reaches 0_C (32_F) measured on a labora-

tory thermometer.

7. Turn unit OFF using start-stop switch (ST).

8. Remove the programming card from the program-

ming/software port and return the unit to normal op-

eration by placing the start-stop switch in the ON

position.

6.21.4 Removing and Ins talling a Module

b. Start unit and check sensor reading on the control

panel. The reading should be 0_C (32_F). If the read-

ing is correct, reinstall sensor; if it is not, continue

with the following.

a. Removal:

1. Disconnect all front wire harness connectors and

move wiring out of way.

c. Turn unit OFF and disconnect power supply.

2 The lower controller mounting is slotted, loosen the

top mounting screw (see Figure 6-18) and lift up and

out.

d. Referto paragraph 6.21 and removecontroller to gain

access to the sensor plugs.

T-309

6-16

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Table 6-2 Sens or Temperature/Res is tance Chart

(+/--.002%)

b. Cut wire(s) 5 cm (2 inches) from shoulder of defec-

tive sensor and discard the defective probe only.

c. Cut one wire of existing cable 40 mm (1-1/2 inch)

shorter than the other wire.

Temperature

Res is tance

(Ohms )

d. Cut one replacement sensor wire (opposite color)

back 40 mm (1-1/2 inch). (See Figure 6-19.)

AMBS,

CPDS

CPSS,

DTS, RTS,

RRS, STS,

SRS

e. Strip back insulation on all wiring 6.3 mm (1/4 inch).

f. Slide a large piece of heat shrink tubing over the

cable, and place the two small pieces of heat shrink

tubing, one over each wire, before adding crimp fit-

tings as shown in Figure 6-20.

-- 3 0

-- 2 5

-- 2 0

-- 1 5

-- 1 0

-- 5

-- 2 2

-- 1 3

-- 4

177,000

130,400

97,070

72,900

55,330

43,200

32,650

25,390

19,900

15,700

12,490

10,000

8,060

1,770,000

1,340,000

970,700

729,000

553,000

423,300

326,500

253,900

199,000

157,100

124,900

100,000

80,600

Sens or (Typical)

Heat Shrink

Tubing (3)

Cable

Large Heat Shrink

Tubing (1)

Figure 6-20 Typical Sens or and Cable Splice

g. Slip crimp fittings over dressed wires (keeping wire

colors together). Make sure wires are pushed into

crimp fittings as faras possibleand crimp with crimp-

ing tool.

6,530

65,300

104

113

122

131

140

149

158

5,330

53,300

h. Solder spliced wires with a 60% tin and 40% lead

Rosincore solder.

4,370

43,700

i. Slide heat shrink tubing over splice so that ends of

tubing cover both ends of crimp as shown in

Figure 6-20.

3,600

36,000

2,900

29,000

2,490

24,900

j. Heat tubing to shrink oversplice. Makesureallseams

are sealed tightly against the wiring to prevent mois-

ture.

2,080

20,800

1,750

17,500

k. Slide large heat shrink tubing over both splices and

shrink.

e. Using the plug connector marked “EC”, that is con-

nected to the back of the controller, locate the sensor

wires (RRS, RTS, SRS, STS, AMBS, DTS, CPDS

OR CPSS as required). Followthose wires to thecon-

nector and using the pins of the plug, measure the

resistance. Values are provided in Table 6-2.

CAUTION

Do not allow moisture to enter wire splice

area as this may affect the sensor resistance.

l. Position sensor in unit as shown in m.Figure 6-21

Slip crimp fittings over dressed wires (keeping wire

colors together). Make sure wires are pushed into

crimp fittings as far as possible and crimp with

crimping tool. and re--check sensor resistance.

Due to the variations and inaccuracies in ohmmeters,

thermometers or other test equipment, a reading

within 2% of the chart value would indicate a good

sensor. If a sensor is defective, the resistance reading

will usually be much higher or lower than the resis-

tance values given.

n. Reinstall sensor, refer to paragraph 6.22.3.

6.22.2 Sens or Replacement

NOTE

The P5 Pre-Trip test must be run to inactivate

probe alarms (refer to paragraph 4.7).

a. Turn unit power OFF, disconnect power supply and

remove sensor assembly from unit.

T-309

6-17

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T.I.R. Bolts

Supply

Air

STS probe

SRS probe

Stream

Ins ulation

Back Panel

Supply Sens or

Mounting

Clamp

Sens or

Wires

Gas keted

Cover

Gas ket

Mounting

Plate

Gas keted

Support

Plate

2.5” Drip Loop

Figure 6-21 Supply Sens or Pos itioning

Sens or DTS

6.22.3 Sens or Re --Ins tallation

a. Sens ors STS and SRS

The DTS sensor must have insulating material placed

completely over the sensor to insure the coil metal

temperature is sensed.

To properly position a supply sensor, the sensor must be

fully inserted into the probe holder. Do not allow heat

shrink covering to contact the probe holder. For proper

placement of the sensor, be sure to position the enlarged

positioning section of the sensor against the the side of

the mounting clamp. This positioning will give the

sensor the optimum amount of exposure to the supply

air stream, and will allow the Controller to operate

correctly. See Figure 6-21.

6.23 MAINTENANCE OF PAINTED SURFACES

The refrigeration unit is protected by a special paint

system against the corrosive atmosphere in which it

normally operates. However, should thepaint system be

damaged, the base metal can corrode. In order to protect

the refrigeration unit from the highly corrosive sea

atmosphere, or if the protective paint system is

scratched or damaged, clean area to bare metal using a

wire brush, emery paper or equivalent cleaning method.

Immediately following cleaning, apply 2--part epoxy

paint to the area. and allow to dry. After the first coat

dries, apply a second coat.

Sens ors RRS and RTS

Reinstall the return sensor as shown in Figure 6-22. For

proper placement of the return sensor, be sure to

position the enlarged positioning section of the sensor

against the the side of the mounting clamp.

6.24 COMPOSITE CONTROL BOX REPAIRS

6.24.1 Introduction

This procedure provides instructions for repair of the

Carrier Transicold composite control box. Damage to

the control box may be in the form of a chip or hole, a

crack, a damaged thread insert or damage to the door

hinge inserts. Generally, the object of the repair must be

to ensure sufficient strength is restored to the damaged

area and the repair must keep the box water tight.

Information on repair kits and repairprocedures foreach

type of damage is provided in the following paragraphs.

Ambient temperature must be above 7°C (45°F) for

proper curing of epoxy repairs.

Mounting

Return Sensor

1.50 in.

(38.1cm)

Clamp

Figure 6-22 Return Sens or Pos itioning

T-309

6-18

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6.24.2 Cracks

The damaged insert must be removed from the control

box. Table 6-5 identifies the drill size and drill depth to

beused foreach insert. A stop ring should beused on the

drill bit to limit the depth.

Cracks in the control box are repaired using a fiberglass

patch over the damaged area. Materials required are

included in theFiberglass Patch Kitsupplied withCrack

Repair Kit, Carrier Transicold part number

76-00724-00SV (see Table 6-3).

a. Center the drill bit on the insert and drill to the pre-

scribed depth.

a. The surface must be clean and dry. Roughen the sur-

face with sandpaper to ensure a good bond.

b. Remove the chips from the drilled hole.

c. Mix the two component epoxy and fill the hole 1/2

way to the top with epoxy.

b. Cut the fiberglass cloth to allow a 25mm (1--inch)

overlap around the area to be repaired.

d. Press the insert in until it is flush with the surface.

c. Stretch and position the cloth over the area to be re-

paired and secure it with masking tape.

e. Wipe away any excess epoxy. The part is ready for

service after the bond material has hardened and is

tack free (approximately 20 minutes)

d. Make up sufficient epoxy glue to cover the cloth by

mixing equal parts of resin and hardener. Saturate the

cloth with the epoxy glue, spreading evenly.

6.24.5 Door Hinge Ins erts

e. Remove the tape and overlap the edge of the cloth

approximately 6 to 12 mm (1/4” to 1/2”) with glue.

If the door hinges have been pulled from the control box

drill and reinstall the hinge as shown in Figure 6-23 and

described in the following steps.

f. Epoxy will dry in 45--60 minutes. When completely

cured (12 hours), use sandpaper to smooth edges of

the patch.

6.24.3 Chips And Holes

Chips and holes in the control box are repaired using a

piece of aluminum or stainless steel to cover the

damaged area. Thematerial can becut to suit andriveted

in place. An adhesive sealant must be used to make the

repair watertight. The adhesive sealant (Sikaflex 221)is

included in Crack Repair Kit Carrier Transicold part

number 76-00724-00SV (see Table 6-3). Do not use an

acetone based silicone sealant (Which can be

identified by a vinegar--like odor).

a. To make up the patch, cut a piece of aluminum or

stainless steel so that it will overlap the damaged area

by at least 40 mm (1 1/2”) on all sides.

b. Choose rivet locations and drill the rivet holes in the

corresponding locations on the control box and patch

piece.

c. Apply the adhesive sealant around the damaged area

to form a seal between the control box and the patch

piece.

Figure 6-23 Door Hinge Repair

Materials needed:

d. Rivet the patch piece in place.

1. Cut two square pieces of 3 mm thick (1/8 inch) alu-

minum or stainless steel approximately 40 mm (1

5/8”) square. These squares will serve as backing

plates.

e. File smooth any rough edges (including rivets) that

may come into contact with wires.

6.24.4 Ins erts

The threaded brass inserts that are molded into the

control box will need to be replaced if the threads

become stripped, or if the insert becomes loose. The

inserts and epoxy are contained in repair kit, Carrier

Transicold part number 76-50084-00 (see Table 6-4).

There are 6 different inserts used in the control box.

Refer to Figure 6-24 for the locations of the various

inserts.

2. Two nuts, bolts (10 -- 24 x 1”) and washers for each

insert that needs repair.

a. Drill a 1/4” hole in the center of each square backing

plate.

b. Pass the bolts through the bolts holes in the door

hinge, then through the control box at the location

where the hinge insert pulled out.

NOTE

c. From inside the control box, slide the backing plates

over the bolts and secure in place with the washers

and nuts.

An epoxy application gun isalso needed, Carri-

er Transicold part number 07 -- 00391 -- 00.

T-309

6-19

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Table 6-3 Crack, Chip & Hole Repair Kit

DESCRIPTION

ITEM

PART NUMBER

76--00724--00SV

76--00724--00Z

02--00067--02Z

98--02339--00

Qty

Crack Repair Kit -- Includes

. . . Fiberglass Patch Kit (Loctite FK--98 or 80265)

. . . Sikaflex 221 Adhesive Sealant (Sikaflex 232--361)

. . . Instruction Sheet

Table 6-4 Ins ert Repair Kit

ITEM

DESCRIPTION

PART NUMBER

76--50084--00

34--06231--01

34--06231--03

34--06231--04

34--06231--05

34--06231--06

34--06231--07

02--0082--00

07--00390--00

98--02338--00

Qty

Insert Repair Kit -- Includes

. . . Insert - 17.53 x 9.91 mm (..690 x .390 in) 1/4--20 Threads

. . . Insert - 15.88 x 6.35 mm (.625 x .250 in) 10-24 Threads

. . . Insert - 25.15 x 7.54 mm (.990 x .297 in) 10-24 Threads

. . . Insert - 10.16 x 9.53 mm (.400 x .375 in) 10-24 Threads

. . . Insert - 12.7 x 9.91 mm (.5 x .390 in) 1/4--20 Threads

. . . Insert - 9.53 x 6.76 mm (.375 x .266 in) 10-24 Threads

. . . Durabond Epoxy E20--HP (Loctite 29314)

. . . Static Mixing Tube (Loctite 983440)

. . . Instruction Sheet

Note: Insert repair procedures require use of an Application Gun, Carrier part number 07--00391--00

Table 6-5 Drill Information

Item

Ins ert part number

34- 06231- 01

34- 06231- 03

34- 06231- 04

34- 06231- 05

34- 06231- 06

34- 06231- 07

Drill s ize and depth

10.3 mm x 17.8 mm deep (.404 in. x .700 in. deep)

6.8 mm x 16.3 mm deep (.266 in. x .640 in. deep)

7.9 mm x 25.4 mm deep (.3125 in. x 1.0 in. deep)

6.9 mm (.270 in.) Drill completely through.

10.3 mm (.404 in.) Drill completely through.

6.8 mm (.266 in.) Drill completely through.

T-309

6-20

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Figure 6-24. Ins ert Location

T-309

6-21

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6.25 COMMUNICATIONS INTERFACE MODULE

INSTALLATION

c.. Remove the circuit breaker panel, with circuit

breaker, from the control box.

d.. Locate, wires CB21/CIA3, CB22/CIA5 and

CB23/CIA7 that have been tied back in the wire

harness. Remove the protective heat shrink fromthe

ends of the wires.

e.. Attach the three wires as addressed to the LOAD

side of the circuit breaker.

f.. Refit the circuit breaker panel.

g. Fit the new RMU into the unit.

h. Remove plugs CIA, CIB and CID from the wiring

harness and attach to the module.

Communications

interface Module

.i. Replace the low voltage shield.

CB1

Table 6-6 Recommended Bolt Torque Values

Figure 6-25. Communications Interface

Ins tallation

BOLT DIA. THREADS

TORQUE

MKG

FREE SPINNING

Units with communication interface module provision

have the required wiring installed. The provision wiring

kit (part number 76--00685--00), includes three

pre--addressed wires installed between the circuit

breakerand communication interface modulelocations.

These wires are to be connected to the module and

circuit breaker to allow the module to communicate

over the power system. To install the module, do the

following:

5.2 in-lbs

9.6 in-lbs

20 in-lbs

23 in-lbs

75 in-lbs

11 ft-lbs

20 ft-lbs

31 ft-lbs

43 ft-lbs

57 ft-lbs

92 ft-lbs

124 ft-lbs

0.05

0.11

0.23

0.26

0.86

1.52

2.76

4.28

5.94

7.88

12.72

17.14

#10

1/4

5/16

3/8

7/16

1/2

9/16

5/8

3/4

WARNING

The Unit Power Plug Must Be Disconnected

To Remove Power From Circuit Breaker

Cb1

NONFREE SPINNING (LOCKNUTS ETC.)

1/4

5/16

3/8

82.5 in-lbs

145.2 in-lbs

22.0 ft-lbs

34.1 ft-lbs

47.3 ft-lbs

62.7 ft-lbs

101.2 ft-lbs

136.4 ft-lbs

0.95

1.67

3.04

4.71

6.54

8.67

13.99

18.86

a.. CB1 is connected to the power system, see wiring

schematic. Ensure that the unit power is off AND

that the unit power plug is disconnected.

7/16

1/2

9/16

5/8

b.. Open control box, see Figure 6-25 and remove low

voltage shield. Open high voltage shield.

3/4

T-309

6-22

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Table 6-7 R-134a Temperature - Pres s ure Chart

Temperature

Vacuum

Temperature

Pres s ure

kPa kg/cm@ bar

“/hg cm/hg kg/cm@ bar

-- 2

-- 1

ps ig

-- 4 0

.35

-- 4 0

.37

14.6

12.3

9.7

49.4

41.6

32.8

22.7

11.9

7.1

37.08

31.25

24.64

17.00

8.89

0.49

0.42

0.33

0.23

0.12

0.07

0.02

24.5 168.9

26.1 180.0

27.8 191.7

29.6 204.1

31.3 215.8

33.2 228.9

35.1 242.0

40.1 276.5

45.5 313.7

51.2 353.0

57.4 395.8

64.1 441.0

71.1 490.2

78.7 542.6

86.7 597.8

95.3 657.1

104.3 719.1

114.0 786.0

124.2 856.4

135.0 930.8

1.72

1.84

1.95

2.08

2.20

2.33

2.47

2.82

3.20

3.60

4.04

4.51

5.00

5.53

6.10

6.70

7.33

8.01

8.73

9.49

1.69

1.80

1.92

2.04

2.16

2.29

2.42

2.76

3.14

3.53

3.96

4.42

4.90

5.43

5.98

6.57

7.19

7.86

8.56

9.31

-- 3 0

-- 2 5

-- 2 0

-- 1 8

-- 1 6

-- 3 4

-- 3 2

-- 2 9

-- 2 8

-- 2 7

6.7

3.5

2.1

5.33

0.6

2.0

1.52

Temperature

Pres s ure

-- 1 4

-- 1 2

-- 1 0

-- 8

-- 6

-- 4

-- 2

-- 2 6

-- 2 4

-- 2 3

-- 2 2

-- 2 1

-- 2 0

-- 1 9

-- 1 8

-- 1 7

-- 1 6

-- 1 4

-- 1 3

-- 1 2

-- 1 1

-- 1 0

-- 9

ps ig

0.4

kPa

1.1

kg/cm@ bar

0.03

0.08

0.14

0.20

0.26

0.32

0.39

0.46

0.53

0.60

0.68

0.76

0.84

0.93

1.02

1.11

1.20

1.30

1.40

1.50

1.61

0.03

0.08

0.14

0.20

0.26

0.32

0.39

0.45

0.52

0.59

0.67

0.74

0.83

0.91

1.00

1.09

1.18

1.28

1.37

1.48

1.58

1.2

8.3

2.0

13.8

20.0

25.5

31.7

36.6

44.8

52.4

59.3

66.9

74.5

82.7

91.0

2.9

3.7

4.6

5.6

6.5

7.6

100

105

110

115

120

125

130

135

140

145

150

155

8.6

9.7

146.4 1009 10.29 10.09

158.4 1092 11.14 10.92

171.2 1180 12.04 11.80

184.6 1273 12.98 12.73

198.7 1370 13.97 13.70

213.6 1473 15.02 14.73

229.2 1580 16.11 15.80

245.6 1693 17.27 16.93

262.9 1813 18.48 18.13

281.1 1938 19.76 19.37

10.8

12.0

13.2

14.5 100.0

15.8 108.9

17.1 117.9

18.5 127.6

19.9 137.2

21.4 147.6

22.9 157.9

-- 8

-- 7

-- 6

-- 4

-- 3

T-309

6-23

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SECTION 7

ELECTRICAL WIRING SCHEMATIC

7.1 INTRODUCTION

This section contains the Electrical Schematics and Wiring Diagrams. The diagrams are presented as follows:

Figure 7-1 Provides the legend for use with all figures.

Figure 7-2 Provides the basic schematic diagram.

Figure 7-3 Provides the basic wiring diagram.

Sequence of operation descriptions for the various modes of operation are provided in paragraph 4.9

LEGEND

SYMBOL

AMBS

DESCRIPTION (Schematic Location)

SYMBOL

DESCRIPTION (Schematic Location)

AMBIENT SENSOR (C--21)

ORV

OIL RETURN SOLENOID VALVE (N--24, H-9)

CONTROLLERS (H-21, H-23)

COMPRESSOR PHASE CONTACTOR (L--11,M--10,P1)

COMPRESSOR PHASE CONTACTOR (L--10,M--11,P2)

CB1

CB2

CIRCUIT BREAKER -- 460 VOLT (J --1)

CIRCUIT BREAKER -- AUTOTRANSFORMER (C--1)

CONDENSER FAN CONTACTOR (M--12, N--5)

COMMUNICATIONS INTERFACE MODULE (A--3)

COOL LIGHT (J --7)

PROBE RECEPTACLE [USDA]

D--21,L--22,M--22)

REMOTE MONITORING RECEPTACLE

(J-6,J --7,K--6,K--7,K--8)

RRS

RTS

SMV

SPT

SRS

RETURN RECORDER SENSOR (K--21)

RETURN TEMPERATURE SENSOR (B--21)

SUCTION MODULATING VALVE (K--24)

SUCTION PRESSURE TRANSDUCER (H--21)

SUPPLY RECORDER SENSOR (K--22)

START -- STOP SWITCH (K--4)

CONDENSER FAN MOTOR (H--12, T-5)

COMPRESSOR MOTOR (T--1)

CPDS

CPSS

COMPRESSOR DISCHARGE SENSOR (A--22)

COMPRESSOR SUCTION SENSOR (D--21)

CHART RECORDER [TEMPERATURE RECORDER]

(K-16)

STS

TCC

SUPPLY TEMPERATURE SENSOR (A--21)

CURRENT SENSOR (M--1)

TransFRESH COMMUNICATIONS

CONNECTOR (D-4)

DHBL

DHBR

DHTL

DHTR

DEFROST HEATER -- BOTTOM LEFT (T--4)

DEFROST HEATER -- BOTTOM RIGHT (R--4)

DEFROST HEATER -- TOP LEFT (T--4)

DEFROST HEATER -- TOP RIGHT (R--4)

DEFROST LIGHT (J --6)

CONTROLLER RELAY -- COOLING (H11)

CONTROLLER RELAY -- HIGH

SPEED EVAPORATOR FANS

(K--13)

TFC

TransFRESH CONTROLLER (G--5)

DPT

DTS

DISCHARGE PRESSURE TRANSDUCER (J --22)

DEFROST TEMPERATURE SENSOR (B--22)

DUAL VOLTAGE MODULE (D--1)

CONTROLLER RELAY -- HEATING (K--15)

CONTROLLER RELAY -- CONDENSER FAN (K--12)

DVM

DVR

TEST POINT (F--17,G--12,H--11,J --12,

J --13,J --15,M--19)

DUAL VOLTAGE RECEPTACLE (F--1)

EVAPORATOR FAN CONTACTOR [HIGH]

(L--13,L--14,P--7,P--10)

TRANSFORMER (M--3)

TRANS AUTO TRANSFORMER 230/460 (D--1)

EVAPORATOR FAN MOTOR (E--13,G--13,T--8,T--11)

TRC

TransFRESH REAR CONNECTOR (E--5)

EVAPORATOR FAN CONTACTOR [LOW]

( M -- 1 4 , P -- 7 , P -- 11 )

ECONOMIZER SOLENOID VALVE (K--17)

CONTROLLER RELAY -- ECONOMIZER SOLENOID

VALVE (E--17)

ESV

FUSE (C--6,D--20,E--20,H--4)

CONTROLLER RELAY -- COOLING (C--11)

FLA

HPS

FULL LOAD AMPS

CONTROLLER RELAY -- UNLOADER SOLENOID

VALVE (E--16)

HIGH PRESSURE SWITCH (G--11)

HEATER CONTACTOR (L--15, N--3)

HUMIDITY SENSOR (F--21)

CONTROLLER RELAY -- LOW SPEED EVAPORATOR

FANS (K--14)

CONTROLLER RELAY -- RM COOL (G--7)

CONTROLLER RELAY -- RM DEFROST (G--6)

CONTROLLER RELAY -- RM INRANGE (G--8)

HTT

HEAT TERMINATION THERMOSTAT (G--15)

INTERROGATOR CONNECTOR [FRONT/REAR]

(P--22,P--21)

CONTROLLER RELAY -- COMPRESSOR PHASE

SEQUENCING (K--10,K--11)

INTERNAL PROTECTOR (E--13,G--13,H--12)

IN RANGE LIGHT (J8)

IRL

LIV

MDS

USV

UNLOADER SOLENOID VALVE (K--16)

WATER PRESSURE SWITCH (E--12)

LIQUID INJECTION SOLENOID VALVE (K-18)

MANUAL DEFROST SWITCH (E--19)

Figure 7-1 LEGEND

T-309

7-1

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Figure 7-2 SCHEMATIC DIAGRAM

T-309

7-2

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Figure 7-3 WIRING DIAGRAM (Sheet 1 of 2)

T-309

7-3

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Figure 7-3 WIRING DIAGRAM (Sheet 2 of 2)

T-309

7-4

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INDEX

Air Cooled Condenser Section, 2-4

Evacuation, 6-3

Alarm, 3-6, 3-10, 3-12, 3-17, 3-27

Evaporator, 6-10

Evaporator Fan, 6-12

Evaporator Section, 2-2

Expansion Module, 3-1, 6-14

Expansion Valves, 6-10

Battery, 1-1

Capacitors, 6-12

Failure Action, 3-4

Checking Superheat, 6-9

Communications, 1-1

Filter--Drier, 6-8

Communications Interface Module, 3-11, 6-21

Compressor, 1-1, 6-5

Fresh Air Makeup, 2-1, 4-1

Frozen Mode, 4-6

Compressor Phase Sequence, 4-5

Compressor Section, 2-3

Condenser Coil, 1-1, 6-8

Condenser Fan, 6-8

Frozen Mode -- Conventional, 3-6

Frozen Mode -- Economy, 3-6

Function Code, 3-14, 3-25

Configuration Identification, 1-1

Configuration Software, 3-3, 3-8

Configuration Variables, 3-13

Control Box, 1-1, 2-5, 6-18

Controller, 3-3, 6-14

General Description, 2-1

Generator Protection, 3-4

Controller Software, 3-3

Heat Lockout, 3-4, 3-6

Heater, 6-10

DataCORDER, 3-7, 3-10, 4-2

DataCORDER Software, 3-7

DataReader, 3-11

Heating Mode, 4-6

High Pressure Switch, 6-7

DataView, 3-11

Defrost Interval, 3-4

Defrost Mode, 4-7

Inspection, 4-1, 4-2

Interrogator, 1-1

Introduction, 1-1

Dehumidification, 1-1

Display Module, 3-2

Index-1

T-309

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INDEX

Refrigeration Circuit, 2-10

Refrigeration System Data, 2-6

Refrigeration Unit -- Front Section, 2-1

Remote Monitoring, 1-1

Key Pad, 3-2

Leak Checking, 6-3

Logging Interval, 3-10

Safety and Protective Devices, 2-8

Sampling Type, 3-10

Scroll Back , 3-10

Manifold Gauge Set, 6-1

Microporcessor System, 3-1

Modes Of Operation, 3-4

Sensor Configuration, 3-8

Sequence Of Operation, 4-5

Service Valves, 6-1

Solenoid Valves, 6-10

Starting, 4-2

Stopping, 4-2

Oil, 6-7

Suction Modulating Valve, 6-13

Operational Software, 3-4, 3-7

Option Descriptions, 1-1

Temperature Control, 3-4, 3-6

Temperature Sensor, 6-17

Thermistor Format, 3-10

Torque Values, 6-21

Painted Surfaces, 6-17

Perishable Mode -- Bulb, 3-5

Perishable Mode -- Conventional, 3-4

Perishable Mode -- Dehumidification, 3-5

Perishable Mode -- Economy, 3-5

Power, 4-1

Upper Air, 1-2

Pre--Trip, 3-7, 3-10, 3-21, 3-26, 4-2

Pressure Readout, 1-1

Probe Check, 4-3

Valve Override Controls, 6-12

Pumping Down, 6-2

Refrigerant Charge, 6-4

Wiring Schematic, 7-1

T-309

Index-2

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