Service Instructions

ManualsBrandsGoodman ManualsCooling & Air Quality3.5 Ton 16 SEER 97% AFUE 80,000 BTU Gas Furnace and Air Conditioner System - Upflow

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SERVICING

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5. Compare the hi-pressure reading to the "Required Liquid Line

Temperature" chart (page 108). Find the hi-pressure value on

the left column. Follow that line right to the column under the

design subcooling value. Where the two intersect is the

required liquid line temperature.

Alternately you can convert the liquid line pressure gauge

reading to temperature by finding the gauge reading in

Temperature - Pressure Chart and reading to the left, find the

temperature in the °F. Column.

6. The difference between the thermometer reading and pres-

sure to temperature conversion is the amount of subcooling.

Add charge to raise subcooling. Recover charge to lower

subcooling.

Subcooling Formula = Sat. Liquid Temp. - Liquid Line Temp.

EXAMPLE:

a. Liquid Line Pressure = 417

b. Corresponding Temp. °F. = 120°

c. Thermometer on Liquid line = 109°F.

To obtain the amount of subcooling subtract 109°F from 120°F.

The difference is 11° subcooling. See the specification sheet or

technical information manual for the design subcooling range

for your unit.

S-110 CHECKING EXPANSION VALVE OPERATION

1. Remove the remote bulb of the expansion valve from the

suction line.

2. Start the system and cool the bulb in a container of ice water,

closing the valve. As you cool the bulb, the suction pressure

should fall and the suction temperature will rise.

3. Next warm the bulb in your hand. As you warm the bulb, the

suction pressure should rise and the suction temperature

will fall.

4. If a temperature or pressure change is noticed, the expansion

valve is operating. If no change is noticed, the valve is

restricted, the power element is faulty, or the equalizer tube

is plugged.

5. Capture the charge, replace the valve and drier, evacuate and

recharge.

S-112 CHECKING RESTRICTED LIQUID LINE

When the system is operating, the liquid line is warm to the touch.

If the liquid line is restricted, a definite temperature drop will be

noticed at the point of restriction. In severe cases, frost will form

at the restriction and extend down the line in the direction of the

flow.

Discharge and suction pressures will be low, giving the appear-

ance of an undercharged unit. However, the unit will have normal

to high subcooling.

Locate the restriction, replace the restricted part, replace drier,

evacuate and recharge.

S-113 OVERCHARGE OF REFRIGERANT

An overcharge of refrigerant is normally indicated by an exces-

sively high head pressure.

An evaporator coil, using an expansion valve metering device,

will basically modulate and control a flooded evaporator and

prevent liquid return to the compressor.

An evaporator coil, using a capillary tube metering device, could

allow refrigerant to return to the compressor under extreme

overcharge conditions. Also with a capillary tube metering

device, extreme cases of insufficient indoor air can cause icing

of the indoor coil and liquid return to the compressor, but the

head pressure would be lower.

There are other causes for high head pressure which may be found

in the "Service Problem Analysis Guide."

If other causes check out normal, an overcharge or a system

containing non-condensables would be indicated.

If this system is observed:

1. Start the system.

2. Remove and capture small quantities of gas from the suction

line dill valve until the head pressure is reduced to normal.

3. Observe the system while running a cooling performance

test. If a shortage of refrigerant is indicated, then the system

contains non-condensables.

S-114 NON-CONDENSABLES

If non-condensables are suspected, shut down the system and

allow the pressures to equalize. Wait at least 15 minutes.

Compare the pressure to the temperature of the coldest coil since

this is where most of the refrigerant will be. If the pressure

indicates a higher temperature than that of the coil temperature,

non-condensables are present.

Non-condensables are removed from the system by first remov-

ing the refrigerant charge, replacing and/or installing liquid line

drier, evacuating and recharging.

CHECKING COMPRESSOR EFFICIENCY

The reason for compressor inefficiency is broken or damaged

scroll flanks on Scroll compressors, reducing the ability of the

compressor to pump refrigerant vapor. The condition of the

scroll flanks is checked in the following manner.

1. Attach gauges to the high and low side of the system.

2. Start the system and run a “Cooling Performance Test. If the

test shows:

a. Below normal high side pressure.

b. Above normal low side pressure.

c. Low temperature difference across coil.

d. Low amp draw at compressor.

And the charge is correct. The compressor is faulty –

replace the compressor.