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Appropriate tightening torque:
Outside
diameter of
Cap
copper pipe
(N·m/kg·cm)
(N·m/kg·cm)
(mm [in])
ø9.52 [3/8]
15/150
ø12.7 [1/2]
20/200
ø15.88 [5/8]
25/250
ø19.05 [3/4]
25/250
ø25.4 [1]
25/250
Caution:
•
Keep the valve closed until the refrigerant charging is finished.
Opening the valve before charging the refrigerant may cause damage
to the unit.
•
Do not use a leak detection additive.
(1) After obtaining to the design pressure (4.15 MPa [602psi]) using nitrogen gas, allow
the system to stand for about one day. If the pressure does not drop, airtightness is
good.
However, if the pressure drops, and the leakage area is unknown, the following bubble
test may also be performed.
(2) After the pressurization described above, spray the flare connection parts, brazed
parts, and other potential leakage areas with a bubbling agent (Kyuboflex, etc.) and
visually check for bubbles.
(3) After the airtight test, wipe off the bubbling agent.
Caution:
Only use R410A refrigerant.
- Using other refrigerants such as R22 or R407C, which contains chlorine,
will deteriorate the refrigerating machine oil or cause the compressor to
malfunction.
2 Evacuation
Evacuate with the valve of the heat source unit closed and evacuate both the
connection piping and the indoor unit from the service port provided on the
valve of the heat source unit using a vacuum pump. (Always evacuate from
the service port of both the high-pressure/gas pipe and the low-pressure/
liquid pipe.) After the vacuum reaches 650 Pa [abs] [0.0943psi/5Torr],
evacuate for at least one hour or more. Then, stop the vacuum pump and
leave it for 1 hour. Ensure the degree of vacuum has not increased. (If the
degree of vacuum increase is larger than 10 Pa [0.01886psi/1.0Torr],
water might present. Apply pressure to dry nitrogen gas up to 0.0
MPa [7.psi] and vacuum again. Repeat the evacuation process three
or more times until the vacuum pressure is lost by 10 Pa or below.)
Finally, seal in with the liquid refrigerant through the high-pressure/gas pipe,
and adjust the low-pressure/liquid piping to obtain an appropriate amount of
the refrigerant for operation.
* Never perform air purging with refrigerant.
[Fig. 10..] (P.10)
A System analyzer
B Low knob
D Valve (heat source
E Low-pressure/liquid
unit)
G Service port
H Three-way joint
J Valve
K R410A cylinder
M Vacuum pump
N To indoor unit
Size of
Shaft
hexagonal
Service port
wrench
(N·m/kg·cm)
(mm)
6/60
4
9/90
4
15/150
6
12/120
30/300
8
30/300
8
Airtight test procedure
C High knob
F High-pressure/gas
pipe
pipe
I Valve
L Scale
O Heat source unit
10.. Airtight test, evacuation, and
refrigerant charging
1 Airtight test
Perform with the valve of the heat source unit closed, charging the
refrigerant pressurize the connection piping and the indoor unit from the
service port provided on the valve of the heat source unit. (Always pressurize
from both the high-pressure/gas pipe and the low-pressure/liquid pipe
service ports.)
[Fig. 10..1] (P.10)
A Nitrogen gas
B To indoor unit
D Low knob
E High knob
G Low-pressure/liquid pipe H High-pressure/gas pipe I Heat source unit
J Service port
Observe the following restrictions when conducting the air tightness test
to prevent negative effects on the refrigerating machine oil. Also, with
nonazeotropic refrigerant (R410A), gas leakage causes the refrigerant
composition to change and affects performance. Therefore, conduct the
airtightness test cautiously.
•
If a flammable gas or air (oxygen) is used as the pressurization
gas, it may catch fire or explode.
Note:
•
Always add the appropriate amount of refrigerant. Also always charge
the system with liquid refrigerant.
•
Use a gauge manifold, charging hose, and other parts for the
refrigerant indicated on the unit.
•
Use a graviometer. (One that can measure down to 0.1 kg [0oz].)
•
Use a vacuum pump with a reverse flow check valve.
(Recommended vacuum gauge: ROBINAIR 1480A Thermistor Vacuum
Gauge or Micron Gauge)
Do not use a manifold gauge to measure vacuum pressure.
Also use a vacuum gauge that reaches 6 Pa [abs] [0.0094psi/0.Torr]
or below after operating for five minutes.
<Triple Evacuation>
•
Evacuate the system to 4,000 microns from both service valves.
System manifold gauges must not be used to measure vacuum.
A micron gauge must be used at all times.
- Break the vacuum with Nitrogen (N2) into the discharge service valve to 0
PSIG.
•
Evacuate the system to 1,00 microns from the suction service valve.
- Break the vacuum with Nitrogen (N2) into the discharge service valve to 0
PSIG.
•
Evacuate the system to 00 microns. System must hold the vacuum at
00 microns for a minimum of 1 hour.
•
Conduct a rise test for a minimum of 0 minutes.
3 Refrigerant Charging
Do not use refrigerant other than the type indicated in the manuals
provided with the unit and on the nameplate.
- Doing so may cause the unit or pipes to burst, or result in explosion or fire
during use, during repair, or at the time of disposal of the unit.
- It may also be in violation of applicable laws.
- MITSUBISHI ELECTRIC CORPORATION cannot be held responsible
for malfunctions or accidents resulting from the use of the wrong type of
refrigerant.
Because the refrigerant used with the unit is nonazerotropic, it must be
charged in the liquid state. Consequently, when charging the unit with
refrigerant from a cylinder, if the cylinder does not have a siphon pipe,
charge the liquid refrigerant by turning the cylinder upside-down as shown in
Fig.10.3.3. If the cylinder has a siphon pipe like that shown in the picture on
Fig.10.3.3, the liquid refrigerant can be charged with the cylinder standing
upright. Follow the cylinder specifications carefully. If the unit should
accidentally be charged with gas refrigerant, replace all the refrigerant with
new refrigerant. Do not use the refrigerant remaining in the cylinder.
[Fig. 10..] (P.10)
A Siphon pipe
B If the R410A cylinder does not have a siphon pipe.
C System analyzer
F Valve
Restriction
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