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Leak detection and evacuation, Leak testing, Evacuation – Heatcraft Refrigeration Products II User Manual

Page 11

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Leak Detection And Evacuation

Leak Testing

After all lines are connected, the entire system must be leak tested. The complete system should be pressurized
to not more than 150 PSIG with refrigerant and dry nitrogen. The use of an electronic type of leak detector is
highly recommended because of its greater sensitivity to small leaks. As a further check, it is recommended that
this pressure be held for a minimum of 12 hours and then rechecked. For a satisfactory installation, the system
must be leak tight.

Leak detection can be carried out in the conventional manner. If HCFC or CFC tracer gas is used, care must be
taken to completely remove all traces of the gas prior to introducing HFC’s. Electronic leak detectors are now
available that will sense HFC’s. This is considered preferable since it removes the possibility of chlorine remaining
in the system after leak testing with HCFC’s and/or HCFC’s. There is a view that even small quantities of chlorine
may act as a catalyst encouraging copper plating and/or corrosion and should therefore be avoided.

Within the last several years, manufacturers have developed fluorescent dye leak detection systems for use with
refrigerants. These dyes mix with the lubricant and, when exposed to an ultraviolet light “fluoresce,” indicate the
location of leaks. Copeland has tested and approved the Rigid “System Safe” dye and found it to be compatible
with the compressor materials in systems.

Evacuation

CAUTION:

Do not use the refrigeration compressor
to evacuate the system. Do not start the
compressor while it is in a vacuum.

Due to the smaller molecule size of HFC’s, they will tend to leak more readily than CFC. Consequently, it is of the
utmost importance that proper system evacuation and leak detection procedures be employed. Copeland
recommends a minimum evacuation to 500 microns. In addition, a vacuum decay test is strongly recommended
to assure there is not a large pressure differential between the system and vacuum pump. Good evacuation
processes include frequent vacuum pump oil changes and large diameter, short hose connections to both high
and low sides of the system preferably using bronze braided hose.

A good, deep vacuum pump should be connected to both the low and high side evacuation valves with copper
tube or high vacuum hoses (1/4” ID minimum). If the compressor has service valves, they should remain closed.
A deep vacuum gauge capable of registering pressure in microns should be attached to the system for pressure
readings.

A shut-off valve between the gauge connection and vacuum pump should be provided to allow the system
pressure to be checked after evacuation. Do not turn off vacuum pump when connected to an evacuated system
before closing shut-off valve.

The vacuum pump should be operated until a pressure a 1,500 microns absolute pressure is reached – at which
time the vacuum should be broken with the refrigerant to be used in the system through a drier until the system
pressure rises above “0” psig.

NOTE:

Refrigerant used during evacuation can not be vented.
Reclaim all used refrigerant. EPA regulations are constantly
being updated. Ensure your procedures follow correct regulations.

Repeat this operation a second time.

Open the compressor’s service valves and evacuate the entire system to 500 microns absolute pressure.

Raise the pressure to 2 psig with the refrigerant and remove the vacuum pump.