Midea MCH2U-18PHH2, MCH3U-27PHH2, MCH5U-48PHH2, MCH4U-36PHH2 Service Manual

1

MULTI OUTDOOR UNITS

SERVICE MANUAL

Multi zone

CONDENSING UNITS

Revision C: ODMI-E-1606

Model Numbers:

MCH2U-18PHH2 MCH3U-27PHH2 MCH4U-36PHH2

MCH5U-48PHH2

WARNING

 Installation MUST conform with local building codes or, in the absence of local

codes, with the National Electrical Code NFPA70/ANSI C1-1993 or current edition
and Canadian Electrical Code Part1 CSA C.22.1.

 The information contained in the manual is intended for use by a qualified service

technician familiar with safety procedures and equipped with the proper tools and
test instruments

 Installation or repairs made by unqualified persons can result in hazards to you

and others.

 Failure to carefully read and follow all instructions in this manual can result in

equipment malfunction, property damage, personal injury and/or death.

Table of Contents

1. Indoor Unit Combination

2. Suggested Indoor Unit Model Numbers

3. Dimension Of Outdoor Unit

4. Refrigerant Cycle Diagram

5. Installation Details

6. Electronic Function

7. Wiring Diagrams

8. Trouble Shooting

9. Disassembly Instructions

2

CONTENTS

1. Indoor Unit Combination .................................................................................................................................... 4

2. Dimension Of Outdoor Unit ................................................................................................................................ 6

3. Refrigerant Cycle Diagram .................................................................................................................................. 7

4. Installation Details ............................................................................................................................................ 10

4.1 Wrench torque sheet for installation .......................................................................................................... 10

4.2 Connecting the cables ................................................................................................................................. 10

4.3 Pipe length and the elevation ..................................................................................................................... 10

4.4 First-Time Installation ................................................................................................................................. 11

4.5 Adding Refrigerant after Long-Term System Operation ............................................................................... 12

4.6 Procedure when servicing the indoor unit refrigeration circuit. ................................................................... 12

4.7 Evacuation after servicing the outdoor unit refrigeration circuit ................................................................. 14

6. Electronic Function ........................................................................................................................................... 15

6.1 Abbreviation ............................................................................................................................................... 15

6.2 Electric Control Working Environment. ....................................................................................................... 15

6.3 Main Protection .......................................................................................................................................... 15

6.4 Control and Functions ................................................................................................................................. 17

7. Wiring Diagrams ............................................................................................................................................... 23

8. Troubleshooting ............................................................................................................................................... 33

8.1Safety .......................................................................................................................................................... 33

8.2 Indoor Unit Error Display ............................................................................................................................. 34

8.3 Outdoor Unit Display .................................................................................................................................. 37

8.4 Diagnosis and Solution ................................................................................................................................ 42

8.5 Trouble Criterion Of Main Parts. ................................................................................................................. 91

9. Disassembly Instructions ................................................................................................................................ 103

 MCH2U-18PHH2 (WCA30 metal plate) .............................................................................................. 103

 MCH3U-27PHH2 (WD30 metal plate) ................................................................................................. 110

3

 MCH4U-36PHH2 (WD30 metal plate) ................................................................................................. 118

 MCH5U-48PHH2 (WE30 metal plate) ................................................................................................. 125

4

1. Indoor Unit Combination

Multi DC

Outdoor

Unit

Nominal
capacity

Suggested

Combination

Limit

1drive 2 5.2kW

12

None

9+9

9+12

12+12

Multi DC

Outdoor

Unit

Nominal
capacity

Suggested

Combination

Limit

1 drive 5 14kW

18+18

None

18+24

24+24

9+9+18

9+9+24

9+12+12

9+12+18

9+12+24

9+18+18

9+18+24

9+24+24

12+12+12

12+12+18

12+12+24

12+18+18

12+18+24

12+24+24

18+18+18

18+18+24

9+9+9+9

9+9+9+12

9+9+9+18

9+9+9+24

9+9+12+12

Multi DC

Outdoor

Unit

Nominal
capacity

Suggested

Combination

Limit

1drive 3 7.8kW

9+9

None

9+12

9+18

12+12

12+18

18+18

9+9+9

9+9+12

9+9+18

9+12+12

9+12+18

12+12+12

Multi DC

Outdoor

Unit

Nominal
capacity

Suggested

Combination

Limit

1 drive 4 10.5kW

9+18

None

12+12

12+18

18+18

9+9+9

9+9+12

9+9+18

9+12+12

9+12+18

9+18+18

12+12+12

12+12+18

12+18+18

9+9+9+9

9+9+9+12

9+9+9+18

9+9+12+12

9+9+12+18

9+12+12+12

12+12+12+12

5

9+9+12+18

9+9+12+24

9+9+18+18

9+9+18+24

9+12+12+12

9+12+12+18

9+12+12+24

9+12+18+18

9+18+18+18

12+12+12+12

12+12+12+18

12+12+12+24

12+12+18+18

9+9+9+9+9

9+9+9+9+12

9+9+9+9+18

9+9+9+9+24

9+9+9+12+12

9+9+9+12+18

9+9+9+18+18

9+9+12+12+12

9+9+12+12+18

9+12+12+12+12

9+12+12+12+18

12+12+12+12+12

6

2. Dimension Of Outdoor Unit

Model

Unit：

W D H W1 A B

MCH2U-18PHH2

mm

845 363 702 923 540 350

inch

33.3

14.3

27.6

36.0

21.3

13.8

MCH3U-27PHH2

mm

946 410 810 1034 673 403

inch

37.2

16.5

31.9

40.6

26.5

15.9

MCH4U-36PHH2

mm

946 410 810 1034 673 403

inch

37.2

16.5

31.9

40.6

26.5

15.9

MCH5U-48PHH2

mm

952 415 1333 1060 634 404

inch

37.5

16.3

52.5

41.7

25.0

15.9

A

B

D

7

3. Refrigerant Cycle Diagram

3.1 Refrigeration circuit drawing of inverter 1 drive 2 type

LIQUID VALVE A

GAS VALVE A

HEAT
EXCHANGE
(EVAPORATOR)

HEAT
EXCHANGE
(CONDENSER)

Compressor

4-WAY VALVE

COOLING

HEATING

T2 Evaporator
temp. sensor
middle

T1 Room
temp. sensor

T3
Condenser
temp. sensor

T5 Discharge
temp. sensor

T4 Ambient
temp. sensor

INDOOR OUTDOOR

EXV A

CAPILIARY A

CHECK VALVE

CAPILIARY TUBE

EXV B CAPILIARY B

LIQUID VALVE B

GAS VALVE B

Accumulator

T2B-A

Evaporator

temp. sensor outlet

T2B-B

3.2 Refrigeration circuit drawing of inverter 1 drive 3 type

LIQUID VALVE A

GAS VALVE A

HEAT
EXCHANGE
(EVAPORATOR)

HEAT
EXCHANGE
(CONDENSER)

Compressor

4-WAY VALVE

COOLING

HEATING

T2 Evaporator
temp. sensor
middle

T1 Room
temp. sensor

T3
Condenser
temp. sensor

T5 Discharge
temp. sensor

T4 Ambient
temp. sensor

INDOOR OUTDOOR

EXV A CAPILIARY A

CHECK VALVE

CAPILIARY TUBE

EXV B

CAPILIARY B

LIQUID VALVE B

GAS VALVE B

EXV C

CAPILIARY C

LIQUID VALVE C

GAS VALVE C

Accumulator

T2B-A

Evaporator

temp. sensor outlet

T2B-B

T2B-C

8

3.3 Refrigeration circuit drawing of inverter 1 drive 4 type

LIQUID VALVE A

GAS VALVE A

HEAT
EXCHANGE
(EVAPORATOR)

HEAT
EXCHANGE
(CONDENSER)

Compressor

4-WAY VALVE

COOLING

HEATING

T2 Evaporator
temp. sensor
middle

T1 Room
temp. sensor

T3
Condenser
temp. sensor

T5 Discharge
temp. sensor

T4 Ambient
temp. sensor

INDOOR OUTDOOR

EXV A

CAPILIARY A

CHECK VALVE

CAPILIARY TUBE

EXV B CAPILIARY B

LIQUID VALVE B

GAS VALVE B

EXV C

CAPILIARY C

LIQUID VALVE C

GAS VALVE C

EXV D CAPILIARY D

LIQUID VALVE D

GAS VALVE D

Accumulator

High pressure
switch

Low pressure
switch

T2B-A

Evaporator

temp. sensor outlet

T2B-B

T2B-C

T2B-D

3.4 Refrigeration circuit drawing of inverter 1 drive 5 type

9

LIQUID VALVE A

GAS VALVE A

HEAT
EXCHANGE
(EVAPORATOR)

HEAT
EXCHANGE
(CONDENSER)

COOLING

HEATING

T2 Evaporator
temp. sensor

T1 Room
temp. sensor

T3
Condenser
temp. sensor

T4 Ambient
temp. sensor

INDOOR OUTDOOR

EXV A CAPILIARY A

CHECK VALVE

CAPILIARY TUBE

EXV B CAPILIARY B

LIQUID VALVE B

GAS VALVE B

EXV C

CAPILIARY C

LIQUID VALVE C

GAS VALVE C

EXV D

CAPILIARY D

LIQUID VALVE D

GAS VALVE D

EXV E

CAPILIARY E

LIQUID VALVE E

GAS VALVE E

Compressor

4-WAY VALVE

T5 Discharge
temp. sensor

Accumulator

High pressure
switch

Low pressure
switch

T2B-A

Evaporator

temp. sensor outlet

T2B-B

T2B-C

T2B-D

T2B-E

10

4. Installation Details

4.1 Wrench torque sheet for

installation

Outside

Torque

Additional

mm inch

N.cm N.cm

Ф6.35 1/4 1500(153kgf.cm) 1600(163kgf.cm)

Ф9.52 3/8 2500(255kgf.cm) 2600(265kgf.cm)

Ф12.7 1/2 3500(357kgf.cm) 3600(367kgf.cm)

4.2 Connecting the cables

The power cord connection should be
selected according to the following
specifications sheet.

Unit

AWG

1 drive 2 type (18K outdoor unit) 14

1 drive 3 type (27K outdoor unit). 14

1 drive 4 type (36K outdoor unit) 12

1 drive 5 type (48K outdoor unit) 10

For indoor unit and outdoor unit
connection line, 16AWG is ok for all.

4.3 Pipe length and the elevation

Maximum piping length and height
difference

1 drive 2 1 drive 3 1 drive 4 1 drive

5
Max. length
for all rooms
(m)

40

(131ft)

60

(197ft)

80

(262ft)

80

(262ft)

Max. length
for one IU
(m)

25

(82ft)

30

(98ft)

35

(115ft)

35

(115ft)

Max. height
difference
between IU
and OU (m)

15

(49.2ft)

15

(49.2ft)

15

(49.2ft)

15

(49.2ft)

Max. height
difference
between IUs
(m)

10

(33ft)

10

(33ft)

10

(33ft)

10

(33ft)

Additional refrigerant charge

1 drive 2 1 drive 3 1 drive 4 1 drive

5
Pre-charge
pipe length

(m)

15

(49.2ft)

22.5

(73.8ft)

30

(98.4ft)

37.5

(123ft)

Additio

nal

refriger

ant

charge

g 15 x

(length

for all

rooms -

15)

15 x

(length

for all

rooms

– 22.5)

15 x

(length

for all

rooms -

30)

15 x

(length

for all

rooms

– 37.5)

oz 0.161

x(lengt

h for all

rooms

– 49.2)

(0.161
x(lengt

h for all

rooms

– 73.8)

0.161x(
length

for all

rooms

– 98.4)

.0.161x

(length

for all

rooms

–123)

Caution:

● Refrigerant pipe diameter is different

according to indoor unit to be connected.
When using the extension pipe, refer to
the tables below.

● When refrigerant pipe diameter is

different from that of the outdoor unit
connector (18K indoor unit) an additional
adapter is required.

Indoor unit

Extension pipe

diameter (mm/inch)

Model

Pipe diameter

(mm/inch)

9K

Liquid 6.35(1/4) Liquid 6.35(1/4)
Gas 9.52(3/8) Gas 9.52(3/8)

12K 18K

Liquid 6.35(1/4) Liquid 6.35(1/4)
Gas 12.7(1/2) Gas 12.7(1/2)

24K

Liquid 9.52 (3/8) Liquid 9.52 (3/8)
Gas 15.9(5/8) Gas 15.9(5/8)

Outdoor unit union diameter (mm/inch)

1 drive 2

Liquid

6.35(1/4)

*2

Gas

9.52(3/8)

*2

1 drive 3

Liquid

6.35(1/4)

*3

Gas

9.52(3/8)

*3

1 drive 4

Liquid

6.35(1/4)

*4

Gas

9.52(3/8)

*3

12.7(1/2) *1

1 drive 5

Liquid

6.35(1/4)

*5

Gas

9.52(3/8)

*3

12.7(1/2) *2

11

4.4 First-Time Installation

Air and moisture in the refrigerant system
cause the following problems:

● Increases in system pressure

● Increases in operating current

● Decreases in cooling and heating

efficiency

● Blocks in capillary tubing caused by

moisture in the refrigerant circuit freezing

● Corrosion of parts in the refrigerant

system caused by water

The indoor units and the pipes between
indoor and outdoor units must be tested for
leakages and evacuated to remove gas and
moisture from the system.

Gas leak check with soap water:

Apply soap water or a liquid neutral
detergent on the connections with a soft
brush to check for leakage in the pipe
connecting points. If bubbles emerge, the
pipes are leaking.

1. Air Purging Using the Vacuum Pump

1. Completely tighten the flare nuts on the

indoor and outdoor units. Confirm that
both the2-way and 3-way valves are set
to the closed position.

2. Connect the charge hose with the push

pin of the Handle Lo to the 3-way valve
gas service port.

3. Connect the charge hose of the Handle
Hi to the vacuum pump.

4. Fully open the Handle Lo of the manifold
valve.

5. Turn on the vacuum pump to begin
evacuation.

6. Conduct a 30-minute evacuation. Check
whether the compound meter indicates -

0.1Mpa(14.5Psi). If the meter does not
indicate -0.1Mpa(14.5Psi) after 30
minutes has elapsed, continue
evacuation for 20 more minutes. If the
pressure does not reach -

0.1Mpa(14.5Psi) after 50 minutes has
elapsed, check if there are any leaks.

Fully close the Handle Lo valve of the
manifold valve and turn off the vacuum
pump. After 5 minutes, confirm that the
gauge needle is not moving.

7. Turn the flare nut on the 3-way valve45°
counterclockwise for 6-7 seconds. Once
gas begins to come out, tighten the flare
nut. Make sure the pressure display on
the pressure indicator is higher than
atmospheric pressure. Then remove the
charge hose from the 3-way valve.

8. Fully open the 2-wayand 3-way valves
and securely tighten the cap on the 3­way valve.

2. Adding refrigerant if the pipe length

exceeds chargeless pipe length

Procedure:

12

1)

Connect the charge hose to the charging
cylinder and open the 2-way and 3-way
valves.

With the charge hose you disconnected
from the vacuum pump, connect it to the
valve at the bottom of the cylinder.

If the refrigerant is R410A, place the
cylinder bottom-up to ensure liquid charging
is possible.

2). Purge the air from the charge hose.

Open the valve at the bottom of the cylinder
and press the check valve on the charge set
(be careful of the liquid refrigerant).

3) Place the charging cylinder onto the
electronic scale and record the weight.

4) Turn on the air conditioner in cooling
mode.

5) Open the valves (Low side) on the charge
set. Charge the system with liquid refrigerant.

6).When the electronic scale displays the
proper weight (refer to the table), disconnect
the charge hose from the 3-way valve’s
service port immediately and turn off the air
conditioner before disconnecting the hose.

7). Mount the valve stem caps and the service
port

Use a torque wrench to tighten the service
port cap to a torque of 18N.m(13.27 ft·lbs).

Be sure to check for gas leaks.

4.5 Adding Refrigerant after Long-

Term System Operation

Procedure

1)

Connect the charge hose to the 3-way
service port and open the 2-way and 3-way
valve.

Connect the charge hose to the valve at the
bottom of the cylinder. If the refrigerant is
R410A, place the cylinder bottom-up to
ensure liquid charge.

2). Purge the air from the charge hose.

Open the valve at the bottom of the cylinder
and press the check valve on the charge set
to purge the air (be careful of the liquid
refrigerant).

3) Place the charging cylinder onto the
electronic scale and record the weight.

4) Turn on the air conditioner in cooling
mode.

5) Open the valves (Low side)on the charge
set and charge the system with liquid
refrigerant.

6).When the electronic scale displays the
proper weight (refer to the gauge and the
pressure of the low side), disconnect the
charge hose from the 3-way valve’s service
port immediately and turn off the air
conditioner before disconnecting the hose.

7). Mount the valve stem caps and the service
port.

Use torque wrench to tighten the service
port cap to a torque of 18N.m(13.27 ft·lbs).

Be sure to check for gas leaks.

4.6 Procedure when servicing the

indoor unit refrigeration circuit.

1. Collecting the refrigerant into the
outdoor unit

13

Procedure

1). Confirm that both the 2-way and 3-way
valves are set to the opened position
Remove the valve stem caps and confirm that
the valve stems are in the opened position.
Be sure to use a hexagonal wrench to operate
the valve stems.

2). Connect the charge hose with the push pin
of handle lo to the 3-way valves gas service
port.

3). Air purging of the charge hose.
Open the handle Lo valve of the manifold
valve slightly to purge air from the charge
hose for 5 seconds and then close it quickly.

4). Set the 2-way valve to the close position.

5). Operate the air conditioner at the cooling
cycle and stop it when the gauge indicates

0.1MPa.

6). Set the 3-way valve to the closed position
immediately
Do this quickly so that the gauge ends up
indicating 0.3 to 0.5Mpa.
Disconnect the charge set, and tighten the 2­way and 3-way valve’s stem nuts.
Use a torque wrench to tighten the 3-way
valves service port cap to a torque of 18N.m.
Be sure to check for gas leakage.

2. Air purging with vacuum pump

1) Completely tighten the flare nuts of the

indoor and outdoor units, confirm that
both the 2-way and 3-way valves are set
to the closed position.

2) Connect the charge hose with the push

pin of handle lo to the 3-way valves gas
service port.

3) Connect the charge hose of handle hi

connection to the vacuum pump.

4) Fully open the handle Lo of the manifold

valve.

5) Operate the vacuum pump to evacuate.

6) Make evacuation for 30 minutes and

check whether the compound meter
indicates -0.1Mpa. If the meter does not
indicate -0.1Mpa after pumping 30
minutes, it should be pumped 20 minutes
more. If the pressure can’t achieve -

0.1Mpa after pumping 50 minutes,
please check if there are some leakage
points.

Fully close the handle Lo valve of the
manifold valve and stop the operation of the
vacuum pump. Confirm that the gauge
needle does not move (approximately 5
minutes after turning off the vacuum pump).

7) Turn the flare nut of the 3-way valves

about 45° counterclockwise for 6 or
7seconds after the gas

coming out, then tighten the flare nut again.
Make sure the pressure display in the

14

pressure indicator is a little higher than the
atmosphere pressure. Then remove the
charge hose from the 3 way valve.

8) Fully open the 2 way valve and 3 way
valve and securely tighten the cap of the
3 way valve.

4.7 Evacuation after servicing the

outdoor unit refrigeration circuit

1. Evacuation of the complete

refrigeration circuit, Indoor and outdoor
unit.

Procedure:

1). Confirm that both the 2-way and 3-way

valves are set to the opened position.

2). Connect the vacuum pump to 3-way

valve’s service port.

3). Evacuation for approximately one hour.

Confirm that the compound meter indicates -

0.1Mpa (500 Microns / 29.9 in,hg).

4). Close the valve (Low side) on the charge

set, turn off the vacuum pump, and confirm
that the gauge needle does not move
(approximately 5 minutes after turning off the
vacuum pump).

5). Disconnect the charge hose from the

vacuum pump.

2. Refrigerant charging

Procedure:

1). Connect the charge hose to the charging
cylinder, open the 2-way valve and the 3-way
valve.
Connect the charge hose which you
disconnected from the vacuum pump to the
valve at the bottom of the cylinder. If the
refrigerant is R410A, make the cylinder
bottom up to ensure liquid charge.

2). Purge the air from the charge hose

Open the valve at the bottom of the cylinder
and press the check valve on the charge set
to purge the air (be careful of the liquid
refrigerant).

3) Put the charging cylinder onto the
electronic scale and record the weight.

4). Open the valves (Low side) on the charge
set and charge the system with liquid
refrigerant
If the system cannot be charge with the
specified amount of refrigerant, or can be
charged with a little at a time (approximately
150g each time) , operating the air conditioner
in the cooling cycle; however, one time is not
sufficient, wait approximately 1 minute and
then repeat the procedure.

5).When the electronic scale displays the
proper weight, disconnect the charge hose
from the 3-way valve’s service port
immediately
If the system has been charged with liquid
refrigerant while operating the air conditioner,
turn off the air conditioner before
disconnecting the hose.

6). Mounted the valve stem caps and the
service port. Use torque wrench to tighten the
service port cap to a torque of 18N·m (13.27
ft·lbs).
Always leak check after servicing the

15

refrigerant system.

For MCH3U-27PHH2/MCH4U­36PHH2/MCH5U-48PHH2
There are one low-pressure centralized valve
and one high-pressure centralized valve, it will
be more time saving when vacuum and
recycle refrigerant. But refer to the previous
instruction when vacuum and recycle
refrigerant.

6. Electronic Function

6.1 Abbreviation

T1: Indoor ambient temperature

T2: Middle indoor heat exchanger coil
temperature

T2B: Indoor heat exchanger exhaust coil
temperature (located on the outdoor unit)

T3: Outdoor heat exchanger pipe
temperature

T4: Outdoor ambient temperature

T5: Compressor discharge temperature

6.2 Electric Control Working

Environment.

6.2.1 Input voltage: 230V.

6.2.2 Input power frequency: 60Hz.

6.2.3 Indoor fan standard working amp.: <1A

6.2.4 Outdoor fan standard working amp.:
<1.5A.

6.2.5 Four-way valve standard amp.: <1A.

6.3 Main Protection

6.3.1 Compressor Restart Delay

---- The compressor takes 1 minute to start
up the first time. Further restarts take 3
minutes.

6.3.2 Temperature Protection of
Compressor Discharge.

When the discharge temperature of the
compressor rises, the running frequency is
limited according to the following rules:

----If 105℃ (221 ℉)≦T5<110℃ (230 ℉),
maintain the current frequency.

16

----If the temperature increase and T5≧110℃

(230 ℉), decrease the frequency to a lower
level every 2 minutes till to F1.

---If T5≧115℃ (239 ℉) for 10 seconds, the

compressor stops and then restart untill
T5<90℃ (194 ℉).

6.3.3 Fan Speed Malfunction

---- If outdoor fan speed is lower than

100RPM or higher than 2400RPM for 60

seconds or more, the unit stops and LED
displays E8 failure code.

6.3.4 Inverter Module Protection.

---- The inverter protection module ensures

that faults related to current, voltage, or
temperature does not damage the inverter.

If these protections are triggered, the A/C
unit stops and the LED displays the failure
code.

The unit restarts 3 minutes after the
protection mechanism has turned off.

6.3.5 Low Voltage Protection

V O LT A G E

N o l im it

V O L T _ LT M _F R EQ 1_ A D D

V O L T _L T M _F R EQ 2_ A D D

Note: If low voltage protection triggers and
voltage is not restored to normal within 3
minutes, the protection remains active
even after a machine restart.

6.3.6 Compressor Current Limit

Protection

The temperature interval for the current limit
is the same as the range of the T4
frequency limit.

Cooling mode:

CoolReturnI The difference between

current limit
and shutdown current

CoolT4Zone5I

Cooling T4≥50℃ current
limit value

CoolT4Zone4I

Cooling 49＞T4≥45℃

current limit value

CoolT4Zone3I

Cooling 44＞T4≥41℃
current limit value

CoolT4Zone2I

Cooling 40﹥T4≥33℃
current limit value

CoolT4Zone1I

Cooling 32＞T4℃current
limit value

CoolStopI Cooling stop protection

current value

Heating mode:

℃

CoolT4Zone5I

50

49

45

CoolT4Zone4I

44

41

40

CoolT4Zone3I

33

32

CoolT4Zone2I

17

℃

15
14 HeatT4Zone4I

10

9 HeatT4Zone3I

6
5 HeatT4Zone2I

HeatT4Zone1I

HeatReturnI The difference between

current limit
and shutdown current

HeatT4Zone4I

Heating

T4≥15℃

current

limit value

HeatT4Zone3I

Heating

14＞T4≥10℃

current limit value

HeatT4Zone2I

Heating

9＞T4≥6℃

current limit value

HeatT4Zone1I

Heating

5＞T4

current limit

value

HeatStopI Heating stop protection

current value

6.3.7 Indoor / Outdoor Units

Communication Protection

If the indoor units do not receive the
feedback signal from the outdoor units for 2
consecutive minutes, the unit stops. The
unit displays the failure code.

6.3.8 High Condenser Coil Temp.

Protection

6.3.9 Outdoor Unit Anti-Freezing
Protection

When T2<4℃ for 250seconds or T2<0℃,
the indoor unit capacity demand is zero and
resumes normal operation when T2>8℃
and the protection time is no less than 3
minutes.

6.3.10 Oil Return

Rules for Operation

1. If the compressor frequency continues to
be lower than the frequency set for setting
time, the unit raises the frequency to the
frequency set for setting time and then
resumes with the former frequency.

2. The EXV continues at 300p while indoor
units maintain their operation.

If the outdoor ambient temperature is higher
than the set frequency during oil return, the
unit stops the oil return process.

6.3.11 Low Outdoor Ambient
Temperature Protection

When the compressor is off and T4 is lower
than -35℃ for 10 seconds, the unit stops
and displays “LP.”

When the compressor is on and T4 remains
lower than -40℃ for 10 seconds, the unit
stops and displays “LP.”

When T4 is no lower than -32℃ for 10
seconds, the unit exits protection.

6.4 Control and Functions

6.4.1 Capacity Request Calculation

Cooling Mode:

T3

Resume

Off

Decrease

Hold

18

T1 Ts

3

1

1

e

c

a

4

2

0

2

3

0

1

f

d

b

Capacity area a b c d e f

Norm code

(N)

3 2 1.5 1 0.5 0

Model 9K 12K 18K 24K

HP 1.0 1.2 1.5 2.5

Note: The final result is an integer.

Use the following table and final capacity
request to confirm the operating
frequency.

Frequency
(Hz)

0

CO

OL_

F1

CO

OL_

F2

…
…

COO
L_F2

4

CO

OL_

F25

Amendatory

capacity

demand.

0 1 2

…
…

24 25

The maximum running frequency is
adjusted according to the outdoor ambient

temperature

℃

55
54 Fmax=

T4FREMAXC0

51.5

50.5 Fmax= T4FREMAXC1

45.5

44.5 Fmax= T4FREMAXC2
39
38 Fmax= T4FREMAXC3
33
32 Fmax= T4FREMAXC4
30
29 Fmax= T4FREMAXC5
22
20 Fmax= T4FREMAXC6
10

8 Fmax= T4FREMAXC7
0

-2 Fmax= T4FREMAXC8

-10

-12 Fmax= T4FREMAXC9

Fmax= T4FREMAXC10

Heating Mode

T1 Ts

4

0

a

3

1

-1

3

1

2

0

b

c

d

e

f

2

Capacity area a b c d e f

Norm code (N) 3 2 1.5 1 0.5 0

Model 9K 12K 18K 24K

HP 1.0 1.2 1.5 2.5

Note: The final result is an integer.

19

Then modify it according to a T2 average
(correction):

Note:Average value of T2：Sum T2 value of
all indoor units)/ (indoor units number

T2 average

Decrease frequency

47

Keep frequency

40 Increase frequency

Use the following table and final capacity
request to confirm the operating
frequency.

Frequency
(Hz) 0

HEA

T_F

1

HEA

T

_F2

…

HEA

T

_F24

HEA

T

_F2

5

Amendatory

capacity

demand.

0 1 2 … 24 25

The maximum running frequency is
adjusted according to the outdoor ambient
temperature

℃
34
33 Standby
28
27 Fmax=T4FREHEATMAX1
25
24 Fmax=T4FREHEATMAX2
22
21 Fmax=T4FREHEATMAX3
19
18 Fmax=T4FREHEATMAX4
17
16 Fmax=T4FREHEATMAX5
15
14 Fmax=T4FREHEATMAX6
12
11 Fmax=T4FREHEATMAX7

6
5 Fmax=T4FREHEATMAX8
1
0 Fmax=T4FREHEATMAX9

-3

-4 Fmax=F21

-7

-8 Fmax=F22

-11

-12 Fmax=F23

-15

-16 Fmax=F24

Fmax=F25

6.4.2 Defrosting Control

Conditions for Defrosting:

After the compressor starts and enters
normal operation, mark the minimum value
of T3 from the 10th to 15th minute as T30.

If any one of the following conditions is
satisfied, the unit enters defrosting mode:

1) If the compressor’s cumulative running
time reaches 29 minutes and T3< TCDI1
and T3＋T30SUBT3ONE≦T30.

20

2) If the compressor cumulative running
time reaches 35 minutes and T3< TCDI2
and T3＋T30SUBT3TWO≦T30.

3) If the compressor cumulative running
time reaches 40 minutes and T3< -24C for 3
minutes.

4) If the compressor cumulative running
time reaches 120 minutes and T3<-15℃.

Defrost Stop Conditions

If any one of the following conditions is
satisfied, defrosting ends and the unit
returns to normal heating mode:

----T3 rises above than TCDE1℃.

----T3 remains at TCDE2℃ or above for 80
seconds.

----The machine runs for 10 consecutive
minutes in defrosting mode.

Defrosting Action：

off on

Cool-F9

10S 30S

TimeA

10S

4-way valve

defrosting Defrosting over

compressor

Indoor fan

Outdoor fan

EXV open

frequency

Max 10 minutes

frequency

Compressor stops

off

Anti-cold control

off

480P 480P for 240s

Condition of ending defrosting:

If any one of following items is satisfied,
defrosting will stop and the machine will turn
to normal heating mode.

① T3 > TempQuitDefrost_ADD ℃;.

② The defrosting time achieves 10min.

③ Turn to other modes or off.

6.4.3 Outdoor Fan Control

6.4.3.1 Cooling Mode

Under normal operating conditions, the
system chooses the running fan speed
according to the ambient temperature:

O

utdoor temperature

℃
45
43 Supper high fan speed
28
26 High fan speed
25
23 Middle fan speed
22
20 Low fan speed
19
17 Supper low fan speed
10

9 Breeze fan speed
0

-1 F fan speed

-5

-6 G fan speed

-10

-11 H fan speed

I fan speed

When low ambient cooling is in effect::

Outdoor fan speed control logic (low
ambient cooling)

When T4 <15 ℃ (59 ℉) and T3 < 30 ℃ (86
℉), the unit enters into low ambient cooling
mode. The outdoor fan chooses a speed

according to T3.
When T3≥38 ℃ (100.4 ℉) or when T4≥20 ℃
(68 ℉), the outdoor fan chooses a speed
according to T4 again.

21

38

Exit low ambient cooling
mode, run with high fan
for 1 minute

Low

30

27

23

off

T3

Increase fan spe ed increase

Keep c urrent fan speed

Decrea se fan speed

Fan st op

LowCoolT3_ON

LowCoo lT3_Down

LowCoo lT3_OFF

6.4.3.2 Heating Mode

Under normal operating conditions, the
system chooses a running fan speed
according to ambient temperature:

Outdoor temperature℃

21

Breeze fan speed
19
18

Supper low fan speed
16
15

Low fan speed
13
12

Middle fan speed
10

0

High fan speed

-2

Supper high fan speed

6.4.4 Electronic Expansion Valve (EXV)
Control

1. EXV remains fully closed while the device
is powering up. EXV then remains on
standby with 350P open. It opens to the
target angle after the compressor starts.

2. EXV closes with -160P when the
compressor stops. Then it remains on
standby with 350P open. It opens to the
target angle after the compressor starts.

3. The action priority for the EXVs is A-B-C­D-E.

4. The compressor and outdoor fan
commence operation only after EXV
initializes.

6.4.4.1 Cooling Mode

The initial open angle of the EXV depends on
the size of the indoor model. The adjustment
range is 100-400p.

When the unit has been running for 3
minutes, the outdoor receives indoor units'
capacity demand and T2B information and
then calculates their average. After
comparing each indoor’s T2B with the

22

average, the outdoor gives the following
modification commands:

---- If the T2B＞average, the relevant valve
needs to open 16p more

---- If the T2B= average, the relevant valve’s
open range remains as is

---- If the T2B＜average, the relevant valve
needs to close 16p more

This modification is carried out every 2
minutes.

6.4.4.2 Heating Mode

The initial open angle of the EXV depends on
the size of the indoor model. The adjustment
range is 150-350p.

When the unit has been running for 3
minutes, the outdoor unit receives the indoor
units' indoor units' capacity demand and T2
information and then calculates their average.

After comparing each indoor unit’s T2 with
the average, the outdoor gives the following
modification commands:

----If the T2＞average+2, the relevant valve
needs to close 16p more

---- If average+2≥the T2≥ average-2, the
relevant valve’s open range remains as is

----If the T2＜average-2, the relevant valve
needs to open 16p more

This modification is carried out every 2
minutes.

6.4.5 Four-Way Valve Control

In heating mode, a four-way valve is opened.

In defrosting, a four-way valve operates
according to the current defrosting action.

In other modes, a four-way valve is closed.

When the unit is switched from heating to
other modes, the four-way valve turns off
after the compressor has been off for 2
consecutive minutes.

Failure or protection (excluding discharge
temperature protection and high/low
pressure protection) causes the four-way
valve to immediately shut down.

23

7. Wiring Diagrams

7.1 Wiring diagram of 1 drive 2 outdoor

MCH2U-18PHH2

24

7.2 Wiring diagram of 1 drive 3 outdoor

MCH3U-27PHH2

25

7.3 Wiring diagram of 1 drive 4 outdoor

MCH4U-36PHH2

26

7.4 Wiring diagram of

MCH5U-48PHH2

27

PCB board of MCH2U-18PHH2, MCH3U-27PHH2

S

N L

H

[1.4] 2015.08.27

1

P E Q

L-OUT

S N L

1

1

1

1

1

CE-KFR80W/BP2T4N1(AC MOTOR)-310.JD.FW.WXWKB.WP1-1

1

2

15

16

RUN

1

1

1

17122300001076

R121

CN36 C N35 CN34

CN33

CN32

P2

P1

C81

R119

C80

C50

C2

_1

D18

D16

D10

CN201

AS1

R116

R115

R114

R113

R112

R111

R98

R43

Q8

Q7

Q6

Q5

CN30

CN18

RY2

CN8

N

CN5

N

CN9

HEAT2

CN2

N

CN6

HEAT1

CN1

4-WAY

SW1

CN15

T2B

CN27

PFC-CONTROL

CN26

TestPort

L1

L2

R110

R109

R108

R107

R106
R105

R104

R103

R97

R57

R56

R55

IC9

D28

D27

C79

C78

R77

DSP1

CN11

AC MOTOR

R46

+

E7

+

E8

+

E11

R12

C11

+

-

~

~

RY8

C77

C76

C75

C74

C73

C72

D1

C71

IC1

R87

IC15

D2

ZR3

ZR2

ZR1

RY7

RY6

RY4

RY3

RY1

R102

R101

R100

R99

R96

R95

R94

R93

R92

R91

R90

R89

R88

R86

R85

R84

R83

R82

R81

R80

R79

R78R76

R75

R74

R73

R72

R71

R70

R69

R68

R67

R66

R65

R63

R62

R61

R60

R59

R58

R54

R53

R52

R51

R50

R48

R47

R45

R44

R42

R41

R39

R38

R37

R36

R35

R34

R33

R32

R31

R30

R28

R27

R26

R25

R24

R23

R22

R21

R20

R19

R18

R17

R16

R15

R14

R13

R11

R10

R9

R8

R7

R6

R5

R4

R3

R2

R1

Q4

Q3

Q2

Q1

PTC1

P-1

GND

IC16

IC14

IC11

IC3

FUSE2

T30A 250VAC

+

E13

+

E12

+

E10

+

E9

+E6+

E4

+

E2

+

E1

D19

D17

D13

D12

D11D9D8

D7

D6

D5

D4

D3

CT1

CONdebug1

CN25

S-A

CN24

D

CN23

S-B

CN22

C

CN21

TO-DRIVE

CN20

S-C

CN19

B

A

CN17

T3/T4

CN16

S-D

CN14

LOW/HIGH

CN13

FAN-C`

CN10

FAN-C

CN7

PAI QI

C59

C58

C57

C56

C55

C54

C53

C51

C49

C47

C46

C44

C43

C41

C40

C39

C38

C37

C35

C33

C32

C31

C30

C28

C26

C25

C24

C23

C22

C21

C20

C17

C16

C15

C14

C13

C12

C10

C9

C5

C4

C3

C1

D20

D15

C60

C61

C62

C63

C64

C65

C66

C67

C68

C69

C70

+

E14

+

E5

IC6

RY5

X1

IC17

C8

C7

C52

C48

C6

CN4

N-IN

CN29

N-OUT

CN28

CN12

CompTop

FUSE1

T5A 250VAC

R120

+

LED1

P-2

GND

CN3

L-IN

R117
R118

D33

D32

D31

R64

R49

R40

R29

IC13

IC12

IC10

IC8

IC7

IC5

IC4

IC2

C45 C36

C34

C29

C27

C19

C18

D34

C42

D14

CN4(N-IN)
power supply

208-230V AC

CN3(L-IN)

connect to the terminal

FUSE2
T30AL/250VAC

T5A 250VAC

FUSE1

CN9-CN8 (controled by RY4 relayer)
connect to the heater
when heater is ON, output 208-230V AC

CN6-CN5 (controled by RY3 relayer)

CN1-CN2 (controled by RY1 relayer)
connect to the 4-WAY
when 4-way is ON, output 208-230VAC

P-1(GND)
connect to the earth

connect to the Earth(Optional)

P-2(GND)

FOR EMC

P1
connect to P2

NO USE

CN20
CN23
CN25

CN16

CN30

connect to the terminal

24VDC Pulse wave betweene (+CN4)-(-CN30)

Signal wire

NO USE

CN36
CN35
CN34

CN10

CN13

FAN-C
FAN-C`

NO USE

CN18

Connect to Electric Expansion Valve

1

2

345

6

+12V DC

+12V DC

+12V DC pulse wave between (+4)-GND

+12V DC pulse wave between (+3)-GND

+12V DC pulse wave between (+2)-GND

+12V DC pulse wave between (+1)-GND

NO USENO USE

CN24 CN22

CN19

status light, by which you can judge the unit Normal or Error

LED1

(standby) Flashing once per second(low speed flashing)

(error) Flashing once p er half second (high speed flashing)

(running) aways on

NO USE

CN21

connect to IPM BOARD CN1

543

2

1

+12V

+5V

Low VOL supply

GND

(+4)-(-3) +5VDC Pulse wave
(+5)-(-3) +5VDC Pulse wave

CN27

room temp sensor RT

pipe temp sensor RT

CN17

Exaust temp sensor RT

CN7

N-OUT

CN15

NO USE

NO USE

CN28

CN14

NO USE

CN12

L-OUT connect to IPM BOARD CN4

connect to IPM BOARD CN5

(L-OUT)-(N-OUT) 208-230V AC

(L-OUT)-(N-OUT) 208-230V AC

connect to the comperssor top temp. sensor

0V DC

NO USE

CN33 connect to DR module RED wire

(L-OUT)-(N-OUT) 208-230V AC

CN32 connect to DR module BLUE wire

NO USE

test port

connect to detector

CN26

connect to DR module

or

28

IPM board of MCH2U-18PHH2, MCH3U-27PHH2

BK

RD

BL

1

K

G

S

CTI 600V

17122000018251

W

V

U

17122000018251

250VAC

Time

Constant

IPM OCP

RD

BK

BL

64

16

J2

EU-KFR8 0W/BP 3(IR311+PS21997+

FAN_DC

SIM682 2+LOCK ).D.13.WP2-1

Pin1

CN7

CN9

CN10

5V→3.3V

3.3V→1.8V

U

V

W

3
2

4

CAUTION HI GH VOLTAGE

1

1

2 4

+

+

CN3

NTC1

R3

D2

41

CN8

Program_Debug

6

1

Online writing

R168

+

DZ10

+

DZ9

+

DZ8

R2

PTC2

J7 J6

J9

J8

F_DC Fan

R167

R166

R165

C81

CN1

CN11

ZR3 ZR2

ZR1

C13

R46

+

E15

C85

IC21

7805

C82

R164

C103

R

1

6

3

R162

R

1

6

1

IC2

CN4

L

CN5

N

CN2

R1_1

R1_2

R1_3

R1_4

R17

IC19

7805

CN13

D7

+

DZ6

C99

IC6

7815

R87

D14

R125

IC10 24LC2 5624LC08

C63

C50

C49

CY1

DZ4

R124

C1

+

E6

+

E5

PTC1

FUSE1
T/3.15A

- +

～

BR2

IC3

T1

IPM1

R121

R67

R90

R84

C7 C12

R

1

1

5

R114

R113

R112

R111

R110

R109

R108

R107

R105

R102

R101

R100

R99

R

9

7

R96

R95

R94

R93

R92

R91

R89

R88

R86

R83

R82

R81

R80

R79

R77

R76

R75

R74

R73

R72

R71

R69

R68

R65

R64

R63

R62

R61

R58

R54

R53

R51

R49

R48

R47

R44

R43

R40

R38 R37

R36

R35

R34 R33 R 31

R30

R29

R28

R27

R26

R25

R

2

4

R23

R21
R20

R19

R18 R16

R15

R14

R13

R12

R11

R10

R9

R8R7R6

R4

Q2

OSC1

LED2+LED1

1

17

49

33

IC14

IC13

IC12

IC11

IC9

IC8

IC7

IC4IC1

C100C101

C4

C95

C96

C97

C98

+

E14

+

E13

E12

+

E11

+

+

E9

+

+

E8

C102

+

E4

+

E1

+

DZ5

+ DZ1

D19

D13

D12

+

D11

D6

+

D3

D1

C78

C77

C76

C75

C74

C73

C72

C71

C70

C69

C68

C67

C

6

6

C65

C64

C

6

2

C

6

1

C60

C59

C58

C57

C56

C54

C53

C

5

2

C51

C47

C46

C45

C44

C43

C42

C41

C40

C39

C37

C36

C35

C34

C33

C32

C31

C30

C29

C28

C27

C26

C25

C24

C23

C22

C21

C20

C19

C18

C17

C16

C

1

5

C14

C11

C10

C8

C5

C3

C2

IGBT1

D20

C6

IC15

IPM2

SIM6822M

+

E2

R106

CN16

R118

R85

R119

R120

R57

+

E3

R117

R116

R122

R123

R70

R78

C38

R50

R66

D9

J4

C80

C55

R138

R137

R136

C84

R135

R143

R133

R132

IC17

Q6

IC16

C79

C83

IC5

R145

Q8

Q9

R144

R141

R148

R147

R146

C90

R98

J3

E27

7815

+

DZ7

E26

+

E25

R

1

3

9

R

1

6

0

C91

D21

R158

R157

R156

R159

C

9

2

IC18

R127

C48

R140

R39

R41

D22

R42

D23

R10_1

R10_2

R10_3

R11_1

R11_2

R11_3

J2

R

1

3

4

BR1

C9

C86

L1

R52

CN_COMP

CN_Reactor

R45

R1

J1

J5

R32
R59

R22

Q1

R103

J

1

0

J12

J11

R83_1

J13

R5

power supply

CN4(L)-CN5(N)

connect to the m ain board no use

fuse1 T/3.15A

Compressor drive EEPROM

online writing

Compressor driv e Program

Debug

DC Fan Driver IP M module

10-200VAC (run ning)

0VAC (standby)

connect to the DC FAN motor

TXD

+12V DC

+5V DC

GND For +12V

RXD

5
4
3
2
1

no use

DC Fan fuse for DC FAN

T/3.15A

10-200VAC (run ning)

0VAC (standby)

connect to the c ompressor

no use

connect to the Reactor

29

PCB board of MCH4U-36PHH2

N

L

SHOW/SW

EARTH

[1.4]2014.06.26

EU-KFR105W/BP3T5N1-350S.D.13.WP1-1

L-OUT

N-OUT

CONNECT TO INVERTER driver

HIGH

LOW

T2B-E

T2B-D

T2B-C

T2B-BT2B-A

TP

T4 T3

S-E

S-D

S-C

S-B

S-A

FAN_OUT

FAN_IN

Q

E

P

AB

C

D

E

202302141206

CN19

D4

R134

R133

R89

R37

+

E12

+

E15

CN10

N

C18

CN9

ZR3

ZR2

ZR1

X1

S

RY8

RY7

RY6

RY5

RY3

RY2

R213

R212

R211

R210

R180

R170

R140

R131

R130

R129

R128

R127

R126

R125

R124

R123

R121

R120

R118

R117

R116

R115

R114

R113

R112

R111

R110

R109

R108

R107

R106

R105

R104

R103

R102

R101

R100

R99

R98

R96

R95

R94

R93

R92

R91

R90

R88

R81

R80

R79

R78

R77

R76

R75

R74

R73

R72

R71

R70

R69

R68

R67

R66

R65

R64

R63

R62

R61

R60

R59

R58

R57

R56

R55

R54

R53

R52

R51

R50

R49

R48

R47

R46

R45

R44

R43

R42

R41

R40

R39R38

R36

R35

R34

R33

R32

R31

R30

R29

R28

R27

R26

R25

R24

R23

R22

R21

R20

R19

R18

R17

R16

R15

R14

R13

R12

R11

R10

R9

R8

R7

R6

R5R4R3

R2

R1

Q5

Q2

PTC1

LED1

L3

IC30

IC22

IC21

IC20

IC19

IC18

IC17

IC16

IC15

IC14

IC13

IC12

IC10

IC9

IC8

IC7 IC6

IC5

IC2

IC1

FUSE2

5A/250V

FUSE1

T30A/250V

E21

E20

+

E19

+

E16+E14

E13

E11

E9

E8

E5

E4

E3

E1

DSP1

DSA1

D28

D27

D26

D25

D24

D23

D22

D21

D20

D19

D18

D17

D16

D15

D14

D13

D12

D11

D10

D9

D8

D7

D6

D5

D3

D2

D1

CONdebug

CN44

HEAT2

CN43

FAN

CN42

C

CN41

C

CN40

HEAT1

CN34

CN33

CN30

CN29

CN28

CN27

CN26

CN22

4-WAY

CN20

CN18

CN17

CN16

CN14

CompTop

CN12

CN11

CN8

CN6

CN5

CN4

N

CN3

N

CN2

N-IN

CN1

L-IN

C103

C98

C97

C96

C95

C94

C93

C92

C91

C90

C72

C70

C69

C68

C67

C66

C65C64

C62

C61

C60

C59

C58

C57

C56

C55

C54

C53

C52

C51

C50

C49

C48

C47

C46

C45

C44

C43

C42

C41

C40

C39

C38

C37

C36

C35

C34

C33 C32

C31

C30

C29

C28

C27

C26

C25

C24

C23

C22

C21

C20

C19

C17

C16

C15

C14

C13

C12

C11

C10

C9C8C7

C6

C5

C4

C3

C2

C1

JP1

JP2

D29

D30

CN23

SSR1

CN7

CN13

P-1

L1

R82

R83

R84

R85

R86

R87

R97

R119

R122

R132

CN35

N

CN37

FAN-L

Q3

Q6

Q7

Q8

Q9

CN36

FAN-H

E2

IC3

Q1

Q4

IC4

ZR4

RY4

CN32

CN38

L2

R135

SW1

CN21

Electric Expansion
Value B

Electric Expansion
Value E

Electric Expansion
Value D

Electric Expansion
Value C

Electric Expansion
Value A

485
communication

testPort
connect to detector

external drive DC fan
motor input terminal

external drive DC fan
motor ouput terminal

current loop
communication A

current loop
communication B

current loop
communication C

current loop
communication D

current loop
communication E

digital display

Fuse
T30A/250V

connect to high and low
pressure sensor

connect to
trmp. sensor

Fuse 5A/250V

connect to earth

CN23 reserve

digital display button

test report
connect to detector

CN43-5,CN43-1/CN41,CN42
AC fan motor capacitor

connector

CN43-4/CN37 CONNECT TO
AC FAN MOTOR(LOW SPEED)

CN43-3/CN36
AC fan motor low speed
connector
CN43-2/CN35
AV fan motor N phase

current loop
communication C

Signal wire

24VDC Pulse wave

connect to the terminal

connect to the terminal

208-230V AC

power supply

room temp sensor

pipe temp sensor

(3.3V)

(3.3V)

high pressure sensor

low pressure sensor

Connect to the Indoor evap.pipe
out temp. sensor
T2B-A、T2B-B、T2B-C、T2B-D、T2B-E

+12V DC pulse wave between (+1)-GND

+12V DC pulse wave between (+2)-GND

+12V DC pulse wave between (+3)-GND

+12V DC pulse wave between (+4)-GND

+12V DC

+12V DC

6 5 4 3 2 1

when 4-way is ON, output 208-230VAC

connect to the 4-WAY

when heater is ON, output 208-230V AC

connect to compressor heater

CN44 L
CN10 N

CN40 L
CN4 N

CN22 L
CN3 N

connect to exhaust
temp. sensor

connect to the terminal

208-230V AC

external drive DC fan
motor connector

T3

T4

electric
heater1

electric
heater 2

30

IPM board of MCH4U-36PHH2

202302141237

PFC-L2

[1.6]2014.10.16

EU-KFR105W/BP2T3N1-350(767).D.13.MP2-1

PFC-L1

CN58

EARTH

C57

C56

6

J146J15

R65

C55

C53

E31

C50

D7

C49

+

E30

C47

C9

ZR1

DZ3

R8

E3

E2

CN55

TO-MAIN

E23

C46

R13

IC3

C113

W

V

U

1

6 7

1011

12

1314

15

3

8

T1

R208

R207

R206

R205

R204

R203

R202

R198

R197

R196

R194

R192

R187

R186

R185

R184

R183

R182

R181

R180

R179

R175

R174

R173

R170

R163

R160

R150

R147

R146

R144

R143

R141

R140

R139

R137

R135

R133

R132

R131

R130

R129

R128

R127

R126

R125

R124

R119

R114

R111

R107

R104

R96

R92

R91

R90

R82

R80

R79

R78

R77

R76

R75

R66

R63

R62

R61

R60

R59

R58

R57

R56

R55

R54

R53

R52

R51

R50

R49

R48

R47

R46

R45

R44

R43

R42

R41

R40

R39

R38

R37

R36

R35

R33

R32

R31

R30

R29

R27

R26

R25

R24

R23

R22

R21

R20

R19

R18

R17

R15

R14

R12

R11

R10

R9

R7

R5

R2

R1

Q2

OSC1

+

LED4+LED3

JR1

J201

6

J1

IPM2

1

IPM1

1

17

49

33

IC20

IC17

IC16

IC15
24C256

IC1424C08

IC10

IC7

IC4

IC2

E34

E33

E27

E25

+

E24

+

E22

+

E21

+

E20

+

E17

E16

E15

E14

E13

E12

E10

E9

+

E8

+

E7

+

E6

+

E5

E4

E1

+

DZ9

+

DZ8

+

DZ7

+

DZ6

+

DZ1

D26

D14

D13

D12

D11

D10

D9

D8

D6

D5

D4

D3

D2

CN57

1

CN56

CN54

L-IN2

CN53

N-IN2

CN52

CN51

CN19

OUTFAN(DC)

C124

C123

C122

C121

C120

C119

C118

C117

C116

C114

C111

C109

C108

C107

C106
C105

C104

C103

C102

C101

C100

C99

C97

C94

C82

C79

C78

C77

C76

C72

C71

C70

C69

C67

C66

C65

C64

C61

C60

C59

C54

C51

C40

C39

C38

C36

C33

C32

C31

C30

C29

C26

C25

C24

C23

C22

C21

C20

C19

C18

C17

C16

C15

C14

C13

C12

C11

C8

C7

C6

C5

C4

C3

C2

C1

BR1

R3

R4

R6

R16

C27

C28

+

E18

C10

+

E19

C34

+

D1

+

D15

+

D16

22

44

23

IC1

C52

D17

R28

6J36

J4

6

J2

6

J5

6

J6

6

J7

6

J8

6J96

J10

6

J11

6

J12

6

J13

C35

C37

C41

C42

C43

C44

C45

E26

E28

E29

IC11

IC12

R34

R64

C48

E11

CN53

power supply

connect to the terminal

208-230V AC

CN54

CN51

CN52

PFC
inductance
terminal

CN58

EATTH

­+

210-300VDC (Running)

CAPACITOR Voltage
290-330VDC (standby)

CN55

TO MAIN

CN19

connect to DC fan motor

U

V

W

10-200VAC (running)

0VAC (standby)

connect to the compressor

U

V

W

10-200VAC (running)

0VAC (standby)

CN57
Debug