Friedrich V(E, H)A09K25 service manual Compressor Checks, From Electrical Shock

Page 21

WARNING

DANGER OF BODILY INJURY OR DEATH

FROM ELECTRICAL SHOCK

When working on high voltage equipment - turn the electrical power off before attaching test leads.

Use test leads with alligator type clips - clip to terminals, turn power on, take reading - turn power off before removing leads.

Compressor Checks

Locked Rotor Voltage (L.R.V.) Test

Locked rotor voltage (L.R.V.) is the actual voltage available at the compressor under a stalled condition.

Single Phase Connections

Disconnect power from unit. Using a voltmeter, attach one lead of the meter to the run "R" terminal on the compressor and the other lead to the common "C" terminal of the com- pressor. Restore power to unit.

CAUTION

Make sure that the ends of the lead do not touch the compressor shell since this will cause a short circuit.

Determine L.R.V.

Start the compressor with the voltmeter attached; then stop the unit. Attempt to restart the compressor within a couple of seconds and immediately read the voltage on the meter. The compressor under these conditions will not start and will usually kick out on overload within a few seconds since the pressures in the system will not have had time to equalize. Voltage should be at or above minimum voltage of 197 VAC, as specifi ed on the rating plate. If less than minimum, check for cause of inadequate power supply; i.e., incorrect wire size, loose electrical connections, etc.

Amperage (L.R.A.) Test

The running amperage of the compressor is the most important of these readings. A running amperage higher than that indicated in the performance data indicates that a problem exists mechanically or electrically.

Single Phase Running and L.R.A. Test

NOTE: Consult the specifi cation and performance section for running amperage. The L.R.A. can also be found on the rating plate.

Select the proper amperage scale and clamp the meter probe around the wire to the "C" terminal of the compressor.

Turn on the unit and read the running amperage on the meter. If the compressor does not start, the reading will indicate the locked rotor amperage (L.R.A.).

External Overload

Some compressors are equipped with an external overload which senses both motor amperage and winding temperature. High motor temperature or amperage heats the overload causing it to open, breaking the common circuit within the compressor.

Heat generated within the compressor shell, usually due to recycling of the motor, is slow to dissipate. It may take anywhere from a few minutes to several hours for the overload to reset.

Checking the External Overload

With power off, remove the leads from compressor terminals. If the compressor is hot, allow the overload to cool before starting check. Using an ohmmeter, test continuity across the terminals of the external overload. If you do not have continuity; this indicates that the overload is open and must be replaced.

Internal Overload

Some compressors are equipped with an internal overload which senses both motor amperage and winding temperature. High motor temperature or amperage heats the overload causing it to open, breaking the common circuit within the compressor. Heat generated within the compressor shell, usually due to recycling of the motor, is slow to dissipate. It may take anywhere from a few minutes to several hours for the overload to reset.

Checking the Internal Overload

A reading of infinity (∞) between any two terminals MAY indicate an open winding. If, however, a reading of infinity

(∞)is obtained between C & R and C & S, accompanied by a resistance reading between S & R, an open internal overload is indicated. Should you obtain this indication, allow the compressor to cool (May take up to 24 hours) then recheck before condemning the compressor. If an open internal overload is indicated, the source of its opening must be determined and corrected. Failure to do so will cause repeat problems with an open overload and/or premature compressor failure. Some possible causes of an open internal overload include insufficient refrigerant charge, restriction in the refrigerant circuit, and excessive current draw.

21

Image 21
Contents VE,HA12K25 VE,HA12K34 VE,HA09K25 VE,HA09K34VE,HA18K25 VE,HA18K34 VE,HA24K25 VE,HA24K34Table of Contents Introduction Serial Number Identification Guide VERT-I-PAKH Suffix Chassis Specifications VERT-I-PAKE & G Suffix Chassis Specifications VERT-I-PAKA D Suffix Chassis Specifications Sequence of Operation Refrigeration AssemblySupply Circuit Electrical SupplySupply Voltage Control Low VoltageHeat Anticipators Room ThermostatsTypical Electrical & Thermostat Wiring Diagrams Typical Electrical & Thermostat Wiring Diagrams Suffix For 208 Volt Models only Move the White Wire AS Shown below Condenser Fan Motors Indoor Blower AirflowBlower Wheel Inspection CoolingChecking External Static Pressure Checking Approximate AirflowElectric Heat Strips Explanation of charts Ductwork PreparationRefrigerant Charging Undercharged Refrigerant Systems Method Of ChargingRestricted Refrigerant Systems Overcharged Refrigerant SystemsMetering Device Capillary Tube Systems Testing CoilReversing Valve Description/Operation Electrical Circuit and CoilTouch Test in Heating/Cooling Cycle Checking Reversing ValveFrom Electrical Shock Compressor ChecksRecommended Procedure for Compressor Replacement Single Phase Resistance TestCapacitor Connections CapacitorsElectric Heat Switch Check Out Electric Heat Switch OperationWiring Diagram Index VHA09K25RTG Suffix only Suffix only Suffix only Page Page Page Page Page Page Page Page Page Electrical Troubleshooting Chart Cooling TON Electrical Troubleshooting Chart Cooling Troubleshooting Chart Cooling Electrical Troubleshooting Chart Heat Pump Page Use Factory Certified Parts