Toshiba RAS-10NAV-E, RAS-10NAV-A, RAS-10NKV-A SERVICE MANUAL

SERVICE MANUAL

AIR-CONDITIONER

RAS-10NKV-E / RAS-10NAV-E

RAS-10NKV-A / RAS-10NAV-A

FILE NO. SVM-05026

SPLIT WALL TYPE

June 2005

1. SPECIFICATIONS

1-1. Specifications
1-2. Operation Characteristic Curve

2. REFRIGERANT R-410A

2-1. Safety During Installation/Servicing
2-2. Refrigerant Piping Installation
2-3. Tools
2-4. Recharging of Refrigerant
2-5. Brazing of Pipes

3. CONSTRUCTION VIEWS

3-1. Indoor Unit
3-2. Outdoor Unit

4. WIRING DIAGRAM

4-1. Indoor Unit
4-2. Outdoor Unit

FILE NO. SVM-05026

CONTENTS

5. SPECIFICATION OF ELECTRICAL PARTS

5-1. Indoor Unit
5-2. Outdoor Unit

6. REFRIGERANT CYCLE DIAGRAM

6-1. Refrigerant Cycle Diagram
6-2. Operation Data

7. CONTROL BLOCK DIA GRAM

7-1. Indoor Unit
7-2. Outdoor Unit (Inverter Assembly)

8. OPERATION DESCRIPTION

8-1. Outlined of Air Conditioner Control
8-2. Description of Operation Circuit
8-3. Temporary Operation
8-4. Auto Restart Function
8-5. Filter Check Lamp
8-6. Remote control

9. INSTALLATION PROCEDURE

9-1. Safety Cautions
9-2. INDOOR UNIT

9.3. OUTDOOR UNIT

− 1 −

10. HO W TO DIA GNOSE THE TROUBLE

10-1. First Confirmation
10-2. Primary Judgement
10-3. Judgement by Flashing LED of Indoor Unit
10-4. Self-Diagnosis by Remote Control (Check Code)
10-5. Judgement of Trouble by Every Symptom
10-6. Check Code 1C (Miswiring in indoor/outdoor units) and 1E
10-7. How to Diagnose Trouble in Outdoor Unit
10-8. How to Check Simply the Main Parts
10-9. How to Simply Judge Whether Outdoor Fan Motor is Good or Bad

11. HOW TO REPLACE THE MAIN PARTS

11-1. Indoor Unit
11-2. Microcomputer
11-3. Outdoor Unit

12. EXPLODED VIEWS AND PARTS LIST

12-1. Indoor Unit (E-Parts Assy)
12-2. Indoor Unit
12-3. Outdoor Unit
12-4. Outdoor Unit (E-Parts Assy)

FILE NO. SVM-05026

– 2 –

1-1. Specifications

FILE NO. SVM-05026

1. SPECIFICATIONS

Unit model

Cooling capacity
Cooling capacity range
Heating capacity
Heating capacity range

Power supply

Electric

characteristics

COP (Cooling / Heating)
Operation noise

Indoor unit Unit model

Outdoor unit Unit model

Piping connection Type

Refrigerant Name of refrigerant

Wiring connection Power supply

Usable temperature range Indoor (Cooling / Heating) (°C)

Indoor
Outdoor

Indoor

Outdoor

Indoor

Outdoor (Cooling / Heating)

Dimension Height

Net weight
Fan motor output
Air flow rate (Cooling / Heating)

Dimension Height

Net weight
Compressor Motor output

Fan motor output
Air flow rate (Cooling / Heating)

Indoor unit Liquid side

Outdoor unit Liquid side

Maximum length (Per unit)
Maximum chargeless length
Maximum height difference

Weight

Operation mode
Running current
Power consumption
Power factor
Operation mode
Running current
Power consumption

Power factor

High (Cooling / Heating)
Medium (Cooling / Heating)
Low (Cooling / Heating)

Width
Depth

Width
Depth

Type
Model

Gas side

Gas side

Interconnection

Outdoor (Cooling / Heating) (°C)

(kW)
(kW)
(kW)

(kW)

(A)
(W)
(%)

(A)
(W)
(%)

(dB• A)
(dB• A)

(dB• A)
(dB• A)

(mm)
(mm)
(mm)

(kg)
(W)

(m3/h)

(mm)
(mm)
(mm)

(kg)
(W)

(W)

(m3/h)

(m)
(m)
(m)

(kg)

RAS-10NKV-E (A)
RAS-10NAV-E (A)

2.5

0.9 − 3.0

3.2

0.7 − 4.0

220− 240V− 1Ph− 50/60Hz

Cooling Heating

0.15 0.15
30 30
87 87

Single rotary type with DC-inverter variable speed control

Cooling Heating

3.33 3.39

730 810

95 95

3.29/3.81
38/39
34/35
27/29
46/47

RAS-10NKV-E (A)

275
790
218

10
20

540/610

RAS-10NAV-E (A)

530
660

240

30

750

DA89X1F-23F

20

1320/1320

Flare connection

∅6.35
∅9.52

∅6.35
∅9.52

10
10

8



R410A

0.64

3 Wires:includes earth (Outdoor)

4 Wires:includes earth



21 − 32 / Up to 27 °C

15 − 43 / − 10 − 24

• The specification may be subject to change without nitice for purpose of improvement.

– 3 –

1-2. Operation Characteristic Curve

<Cooling> <Heating>

FILE NO. SVM-05026

6

5

10NAV

4

3

Current (A)

2

Conditions

Indoor : DB 27°

1

0

020406080100

Outdoor : DB 35°C
Air flow : High
Pipe lenght : 5m
Voltage : 230V

Compressor speed (rps)

C/WB 19°C

6

5

4

3

Current (A)

2

1

0

020406080100

1-3. Capacity Variation Ratio According to Temperature

<Cooling> <Heating>

10NAV

Conditions

Indoor : DB 20°C
Outdoor : DB 7°C/WB 6°C
Air flow : High
Pipe lenght : 5m
Voltage : 230V

Compressor speed (rps)

105

100

95

90

85

80

75

Capacity ratio (%)

70

65

60

55

50

32 33 34 35 36 37 38 39 40 41 42 43

Current Limited Start

a

Conditions
Indoor : DB 27°C/WB 19°C
Indoor air flow : High
Pipe lengthh 5m

Outdoor temp. (°C)

* Capacity ratio : 100% = 2.5 kW (Cooling)

: 100% = 3.2 kW (Heating)

120

110

100

90

80

70

60

Capacity ratio (%)

50

40

30

20

10

-10 -9

a

Conditions
Indoor : DB 20°C
Indoor air flow : High
Pipe lengthh : 5m

-7

-8

-3

-5 -4

-6

Outdoor temp. (°C)

-1 0 12345678910

-2

– 4 –

2. REFRIGERANT R410A

FILE NO. SVM-05026

This air conditioner adopts the new refrigerant HFC
(R410A) which does not damage the ozone layer.

The working pressure of the new refrigerant R410A is

1.6 times higher than conventional refrigerant (R22).
The refrigerating oil is also changed in accordance
with change of refrigerant, so be careful that water,
dust, and existing refrigerant or refrigerating oil are not
entered in the refrigerant cycle of the air conditioner
using the new refrigerant during installation work or
servicing time.

The next section describes the precautions for air
conditioner using the new refrigerant. Conforming to
contents of the next section together with the general
cautions included in this manual, perform the correct
and safe work.

2-1.Safety During Installation/Servicing

As R410A’s pressure is about 1.6 times higher than
that of R22, improper installation/servicing may cause
a serious trouble. By using tools and materials exclu­sive for R410A, it is necessary to carry out installation/
servicing safely while taking the following precautions
into consideration.

(1) Never use refrigerant other than R410A in an air

conditioner which is designed to operate with
R410A.
If other refrigerant than R410A is mixed, pressure
in the refrigeration cycle becomes abnormally
high, and it may cause personal injury, etc. by a
rupture.

(2) Confirm the used refrigerant name, and use tools

and materials exclusive for the refrigerant R410A.
The refrigerant name R410A is indicated on the
visible place of the outdoor unit of the air condi­tioner using R410A as refrigerant. To prevent
mischarging, the diameter of the service port
differs from that of R22

(3) If a refrigeration gas leakage occurs during instal-

lation/servicing, be sure to ventilate fully.
If the refrigerant gas comes into contact with fire,
a poisonous gas may occur.

(4) When installing or removing an air conditioner,

do not allow air or moisture to remain in the
refrigeration cycle. Otherwise, pressure in the
refrigeration cycle may become abnormally high
so that a rupture of personal injury may be
caused.

(5) After completion of installation work, check to

make sure that there is no refrigeration gas
leakage.
If the refrigerant gas leaks into the room, coming
into contact with fire in the fan-driven heater,
space heater, etc., a poisonous gas may occur.

(6) When an air conditioning system charged with a

large volume of refrigerant is installed in a small
room, it is necessary to exercise care so that,
even when refrigerant leaks, its concentration
does not exceed the marginal level.
If the refrigerant gas leakage occurs and its
concentration exceeds the marginal level, an
oxygen starvation accident may result.

(7) Be sure to carry out installation or removal

according to the installation manual.
Improper installation may cause refrigeration
trouble, water leakage, electric shock, fire, etc.

(8) Unauthorized modifications to the air conditioner

may be dangerous. If a breakdown occurs please
call a qualified air conditioner technician or
electrician.
Improper repair’s may result in water leakage,
electric shock and fire, etc.

2-2.Refrigerant Piping Installation

2-2-1. Piping materials and joints used

For the refrigerant piping installation, copper pipes and
joints are mainly used. Copper pipes and joints suit­able for the refrigerant must be chosen and installed.
Furthermore, it is necessary to use clean copper pipes
and joints whose interior surfaces are less affected by
contaminants.

(1) Copper Pipes

It is necessary to use seamless copper pipes
which are made of either copper or copper alloy
and it is desirable that the amount of residual oil is
less than 40 mg/10 m. Do not use copper pipes
having a collapsed, deformed or discolored
portion (especially on the interior surface).
Otherwise, the expansion valve or capillary tube
may become blocked with contaminants.
As an air conditioner using R410A incurs pressure
higher than when using R22, it is necessary to
choose adequate materials.
Thicknesses of copper pipes used with R410A are
as shown in Table 2-2-1. Never use copper pipes
thinner than 0.8 mm even when it is available on
the market.

– 5 –

FILE NO. SVM-05026

T able 2-2-1 Thicknesses of annealed copper pipes

Thickness (mm)

Nominal diameter Outer diameter (mm) R-410A R-22

1/4 6.35 0.80 0.80
3/8 9.52 0.80 0.80
1/2 12.70 0.80 0.80
5/8 15.88 1.00 1.00

(2) Joints

For copper pipes, flare joints or socket joints are
used. Prior to use, be sure to remove all
contaminants.

a) Flare Joints

Flare joints used to connect the copper pipes
cannot be used for pipings whose outer
diameter exceeds 20 mm. In such a case,
socket joints can be used.
Sizes of flare pipe ends, flare joint ends and
flare nuts are as shown in Tables 2-2-3 to 2-2-6
below.

Table 2-2-2 Minimum thicknesses of socket joints

Nominal diameter

Reference outer diameter of Minimum joint thickness

1/4 6.35 0.50
3/8 9.52 0.60
1/2 12.70 0.70
5/8 15.88 0.80

b) Socket Joints

Socket joints are such that they are brazed for
connections, and used mainly for thick pipings
whose diameter is larger than 20 mm.
Thicknesses of socket joints are as shown in
Table 2-2-2.

copper pipe jointed (mm) (mm)

2-2-1. Processing of piping materials

When performing the refrigerant piping installation,
care should be taken to ensure that water or dust does
not enter the pipe interior, that no other oil other than
lubricating oils used in the installed air conditioner is
used, and that refrigerant does not leak. When using
lubricating oils in the piping processing, use such
lubricating oils whose water content has been removed.
When stored, be sure to seal the container with an
airtight cap or any other cover.

(1) Flare Processing Procedures and Precautions

a) Cutting the Pipe

By means of a pipe cutter, slowly cut the pipe
so that it is not deformed.

b) Removing Burrs and Chips

If the flared section has chips or burrs,
refrigerant leakage may occur. Carefully
remove all burrs and clean the cut surface
before installation.

c) Insertion of Flare Nut

– 6 –

d) Flare Processing

Make certain that a clamp bar and copper pipe
have been cleaned.
By means of the clamp bar, perform the flare
processing correctly.
Use either a flare tool for R-410A or conven­tional flare tool.
Flare processing dimensions differ according to
the type of flare tool. When using a conven­tional flare tool, be sure to secure “dimension A”
by using a gauge for size adjustment.

D

A

Fig. 2-2-1 Flare pr ocessing dimensions

FILE NO. SVM-05026

T able 2-2-3 Dimensions related to flare pr ocessing for R-410A

Nominal

diameter

1/4 6.35 0.8 0 to 0.5 1.0 to 1.5 1.5 to 2.0
3/8 9.52 0.8 0 to 0.5 1.0 to 1.5 1.5 to 2.0
1/2 12.70 0.8 0 to 0.5 1.0 to 1.5 2.0 to 2.5
5/8 15.88 1.0 0 to 0.5 1.0 to 1.5 2.0 to 2.5

Nominal

diameter

1/4 6.35 0.8 0 to 0.5 0.5 to 1.0 1.0 to 1.5
3/8 9.52 0.8 0 to 0.5 0.5 to 1.0 1.0 to 1.5
1/2 12.70 0.8 0 to 0.5 0.5 to 1.0 1.0 to 2.0

Outer

diameter

(mm)

T able 2-2-4 Dimensions related to flare pr ocessing for R-22

Outer

diameter

(mm)

Thickness

(mm)

Thickness

(mm)

Flare tool for R-410A

clutch type

Flare tool for R-410A

clutch type

A (mm)

Con ventional flare tool

Clutch type Wing nut type

A (mm)

Con ventional flare tool

Clutch type Wing nut type

5/8 15.88 1.0 0 to 0.5 0.5 to 1.0 1.0 to 2.0

T able 2-2-5 Flare and flare n ut dimensions for R-410A

Nominal

diameter

1/4 6.35 0.8 9.1 9.2 6.5 13 17
3/8 9.52 0.8 13.2 13.5 9.7 20 22
1/2 12.70 0.8 16.6 16.0 12.9 23 26
5/8 15.88 1.0 19.7 19.0 16.0 25 29

Nominal

diameter

1/4 6.35 0.8 9.0 9.2 6.5 13 17

Outer

diameter

(mm)

Outer

diameter

(mm)

Thickness

(mm)

T able 2-2-6 Flare and flare n ut dimensions for R-22

Thickness

(mm)

ABCD

ABCD

Dimension (mm)

Dimension (mm)

Flare nut

width

(mm)

Flare nut

width

(mm)

3/8 9.52 0.8 13.0 13.5 9.7 20 22
1/2 12.70 0.8 16.2 16.0 12.9 20 24
5/8 15.88 1.0 19.7 19.0 16.0 23 27
3/4 19.05 1.0 23.3 24.0 19.2 34 36

– 7 –

FILE NO. SVM-05026

Fig. 2-2-2 Relations between flare n ut and flare seal surface

(2) Flare Connecting Procedures and Precautions

a) Make sure that the flare and union portions do

not have any scar or dust, etc.

b) Correctly align the processed flare surface with

the union axis.

c) Tighten the flare with designated torque by

means of a torque wrench. The tightening
torque for R-410A is the same as that for
conventional R-22. Incidentally, when the
torque is weak, the gas leakage may occur.

T able 2-2-7 Tightening torque of flare for R-410A [Reference v alues]

Nominal Outer diameter Tightening torque

diameter (mm) N·m (kgf·cm)

1/4 6.35 14 to 18 (140 to 180) 16 (160), 18 (180)
3/8 9.52 33 to 42 (330 to 420) 42 (420)
1/2 12.70 50 to 62 (500 to 620) 55 (550)
5/8 15.88 63 to 77 (630 to 770) 65 (650)

When it is strong, the flare nut may crack and
may be made non-removable. When choosing
the tightening torque, comply with values
designated by manufacturers. Table 2-2-7
shows reference values.

Note:

When applying oil to the flare surface, be sure to use
oil designated by the manufacturer. If any other oil is
used, the lubricating oils may deteriorate and cause
the compressor to burn out.

Tightening torque of torque

wrenches available on the market

N·m (kgf·m)

– 8 –

FILE NO. SVM-05026

2-3. T ools

2-3-1. Required tools

The service por t diameter of packed valve of the outdoor unit in the air conditioner using R-410A is changed to
prevent mixing of other refrigerant. To reinforce the pressure-resisting strength, flare processing dimensions and
opposite side dimension of flare nut (For ∅12.70 copper pipe) of the refrigerant piping are lengthened.

The used refrigerating oil is changed, and mixing of oil may cause a trouble such as generation of sludge,
clogging of capillary, etc. Accordingly, the tools to be used are classified into the following three types.

(1) Tools exclusive for R-410A (Those which cannot be used for conventional refrigerant (R-22))
(2) Tools exclusive for R-410A, but can be also used for conventional refrigerant (R-22)
(3) Tools commonly used for R-410A and for conventional refrigerant (R-22)
The table below shows the tools exclusive for R-410A and their interchangeability.

Tools exclusive for R-410A (The following tools for R-410A are required.)

Tools whose specifications are changed for R-410A and their interchangeability

R-410A air conditioner Conventional air

installation conditioner installation

No. Used tool Usage Existence of Whether Whether new equipment

new equipment conventional can be used with
for R-410A equipment can conventional refrigerant

be used

1 Flare tool Pipe flaring Yes *(Note 1)
2 Copper pipe gauge Flaring by

for adjusting projection conventional flare Yes *(Note 1) *(Note 1)
margin tool

3 Torque wrench Connection of

(For ∅12.70) flare nut

4 Gauge manifold
5 Charge hose

6 Vacuum pump adapter Vacuum evacuating Yes

Electronic balance for

7

refrigerant charging

8 Refrigerant cylinder Refrigerant charge Yes
9 Leakage detector Gas leakage check Yes
! Charging cylinder Refrigerant charge (Note 2)

Evacuating,
refrigerant charge, Yes
run check, etc.

Refrigerant charge Yes

Yes

(Note 1) When flaring is carried out for R-410A using the conventional flare tools, adjustment of projection

margin is necessary. For this adjustment, a copper pipe gauge, etc. are necessary.

(Note 2) Charging cylinder for R-410A is being currently developed.

General tools (Conventional tools can be used.)

In addition to the above exclusive tools, the following equipments which serve also for R-22 are necessary as
the general tools.
(1) Vacuum pump (4) Reamer (9) Hole core drill (∅65)

Use vacuum pump by (5) Pipe bender (10) Hexagon wrench

attaching vacuum pump adapter. (6) Level vial (Opposite side 5 mm)
(2) Torque wrench (For ∅6.35) (7) Screwdriver (+, –) (11) Tape measure
(3) Pipe cutter (8) Spanner of Monkey wrench (12) Metal saw

Also prepare the following equipments for other installation method and run check.
(1) Clamp meter (3) Insulation resistance tester
(2) Thermometer (4) Electroscope

– 9 –

FILE NO. SVM-05026

2-4. Recharging of Refrigerant

When it is necessary to recharge refrigerant, charge the specified amount of new refrigerant according to the
following steps.

Recover the refrigerant, and check no refrigerant
remains in the equipment.

When the compound gauge’s pointer has indi­cated -0.1 Mpa (-76 cmHg), place the handle Low

Connect the charge hose to packed valve service
port at the outdoor unit’s gas side.

in the fully closed position, and turn off the
vacuum pump’s power switch.

Connect the charge hose of the vacuum pump
adapter.

Open fully both packed valves at liquid and gas
sides.

Keep the status as it is for 1 to 2 minutes, and
ensure that the compound gauge’s pointer does
not return.

Set the refrigerant cylinder to the electronic
balance, connect the connecting hose to the
cylinder and the connecting port of the electronic
balance, and charge liquid refrigerant.

Place the handle of the gauge manifold Low in

(For refrigerant charging, see the figure below.)

the fully opened position, and turn on the vacuum
pump’s power switch. Then, evacuating the
refrigerant in the cycle.

1 Never charge refrigerant exceeding the specified amount.
2 If the specified amount of refrigerant cannot be charged, charge refrigerant bit by bit in COOL mode.
3 Do not carry out additional charging.

When additional charging is carried out if refrigerant leaks, the refrigerant composition changes in the
refrigeration cycle, that is characteristics of the air conditioner changes, refrigerant exceeding the
specified amount is charged, and working pressure in the refrigeration cycle becomes abnormally high
pressure, and may cause a rupture or personal injury.

(INDOOR unit)

Refrigerant cylinder

(With siphon pipe)

Check valve

Open/Close valve

for charging

Electronic balance for refrigerant charging

Fig. 2-4-1 Configuration of refrigerant charging

(Liquid side)

(Gas side)

– 10 –

(OUTDOOR unit)

Opened

Closed

Service port

FILE NO. SVM-05026

1 Be sure to make setting so that liquid can be charged.
2 When using a cylinder equipped with a siphon, liquid can be charged without turning it upside down.

It is necessary for charging refrigerant under condition of liquid because R-410A is mixed type of refrigerant.
Accordingly, when charging refrigerant from the refrigerant cylinder to the equipment, charge it turning the
cylinder upside down if cylinder is not equipped with siphon.

[Cylinder with siphon][Cylinder with siphon] [Cylinder without siphon]

Gauge manifold

OUTDOOR unit

Refrigerant

cylinder

Gauge manifold

OUTDOOR unit

Refrigerant

cylinder

Electronic

balance

R-410A refrigerant is HFC mixed refrigerant.
Therefore, if it is charged with gas, the composition
of the charged refrigerant changes and the
characteristics of the equipment varies.

2-5. Brazing of Pipes

2-5-1. Materials f or brazing
(1) Silver brazing filler

Silver brazing filler is an alloy mainly composed of
silver and copper. It is used to join iron, copper or
copper alloy, and is relatively expensive though it
excels in solderability.

(2) Phosphor bronze brazing filler

Phosphor bronze brazing filler is generally used to
join copper or copper alloy.

(3) Low temperature brazing filler

Low temperature brazing filler is generally called
solder, and is an alloy of tin and lead. Since it is
weak in adhesive strength, do not use it for
refrigerant pipes.

Electronic

balance

Siphon

Fig. 2-4-2

1 Phosphor bronze brazing filler tends to react

with sulfur and produce a fragile compound
water solution, which may cause a gas leakage.
Therefore, use any other type of brazing filler at
a hot spring resort, etc., and coat the surface
with a paint.

2 When performing brazing again at time of

servicing, use the same type of brazing filler.

2-5-2. Flux
(1) Reason why flux is necessar y

• By removing the oxide film and any foreign
matter on the metal surface, it assists the flow of
brazing filler.

• In the brazing process, it prevents the metal
surface from being oxidized.

• By reducing the brazing filler’s surface tension,
the brazing filler adheres better to the treated
metal.

– 11 –

FILE NO. SVM-05026

(2) Characteristics required f or flux

• Activated temperature of flux coincides with the
brazing temperature.

• Due to a wide effective temperature range, flux
is hard to carbonize.

• It is easy to remove slag after brazing.

• The corrosive action to the treated metal and

brazing filler is minimum.

• It excels in coating performance and is harmless
to the human body.

As the flux works in a complicated manner as
described above, it is necessary to select an
adequate type of flux according tot he type and
shape of treated metal, type of brazing filler and
brazing method, etc.

(3) T ypes of flux

• Non-corrosive flux

Generally, it is a compound of borax and boric
acid.
It is effective in case where the brazing
temperature is higher than 800°C.

• Activated flux

Most of fluxes generally used for silver brazing
are this type.
It features an increased oxide film removing
capability due to the addition of compounds
such as potassium fluoride, potassium chloride
and sodium fluoride to the borax-boric acid
compound.

(4) Piping materials f or brazing and used brazing

filler/flux

2-5-3. Brazing

As brazing work requires sophisticated techniques,
experiences based upon a theoretical knowledge, it
must be performed by a person qualified.
In order to prevent the oxide film from occurring in the
pipe interior during brazing, it is effective to proceed
with brazing while letting dry Nitrogen gas (N2) flow.

Never use gas other than Nitr ogen gas.

(1) Brazing method to prevent oxidation

1 Attach a reducing valve and a flow-meter to the

Nitrogen gas cylinder.

2 Use a copper pipe to direct the piping material,

and attach a flow-meter to the cylinder.

3 Apply a seal into the clearance between the

piping material and inserted copper pipe for
Nitrogen in order to prevent backflow of the
Nitrogen gas.

4 When the Nitrogen gas is flowing, be sure to

keep the piping end open.

5 Adjust the flow rate of Nitrogen gas so that it is

lower than 0.05 m3/Hr or 0.02 Mpa (0.2 kgf/
cm2) by means of the reducing valve.

6 After performing the steps above, keep the

Nitrogen gas flowing until the pipe cools down
to a certain extent (temperature at which pipes
are touchable with hands).

7 Remove the flux completely after brazing.

M

Flow meter

Piping Used brazing Used

material filler flux

Copper - Copper Phosphor copper Do not use

Copper - Iron Silver Paste flux

Iron - Iron Silver Vapor flux

1 Do not enter flux into the refrigeration cycle.
2 When chlorine contained in the flux remains

within the pipe, the lubricating oil deteriorates.
Therefore, use a flux which does not contain
chloring.

3 When adding water to the flux, use water which

does not contain chlorine (e.g. distilled water or
ion-exchange water).

4 Remove the flux after brazing.

Stop valve

Nitrogen gas

cylinder

From Nitrogen cylinder

Pipe

Nitrogen
gas

Rubber plug

Fig. 2-5-1 Prevention of oxidation during brazing

– 12 –

3-1. Indoor Unit

Front panel

FILE NO. SVM-05026

3. CONSTRUCTION VIEWS

60

6

Knock out system

Air inlet

Air filter

Heat exchanger

790

275

Air outlet

120 80

590

Hanger

64

218

60

6

48

Knock out system

48

53

Drain hose (0.54m)

Hanger

320

Connecting pipe (0.33m)

620

235 235

215 215

Minimum
distance
to ceiling

Hanger

65 or more

45

Minimum
distance
to ceiling

275

170 or more

Hanger

Installation plate outline

– 13 –

Center line

Connecting pipe (0.43m)
(Flare∅6.35)

For stud bolt
(

∅ 8~∅

10)

For stud bolt (

26

Minimum
distance
to ceiling

170 or more

Hanger

150150 160160

32

9090

∅

6)

4519040

57 18

Wireless remote control

160

3-2. Outdoor Unit

A Detail Drawing (Back Leg)

660

50

265

273.5

36

∅6 Hole

R 15

R 5.5

A

59.5

273.5

Fan guard

∅25Drain outlet

97

2-∅11x14 hole
(for ∅8-∅10 anchor bolt)

B

FILE NO. SVM-05026

B Detail Drawing (Front Leg)

265

273.5

∅6 Hole

∅11x14 Hole

36
50

R 15

660

Cover PV

242

530

∅420

500 97.5
660

Z View

56

(11)

126

48

Z

(12.5)273.5 (pitch)

297

Liquid side

(Flare ∅6.35)
Gas side
(Flare ∅9.52)

54

Service port

Installation dimension

100 or more

325

100 or more

Air outlet

600

Air inlet

600 or more

– 14 –

600 or more

4x∅11x14 Long holes (for ∅8-∅10 anchor bolt)

4-1. Indoor Unit

COLOR INDICATION

:

BROWN

BRW

:

RED

RED

:

WHITE

WHI

:

YELLOW

YEL

:

BLUE

BLU

:

BLACK

BLK

:

GRAY

GRY

:

PINK

PNK

:

ORANGE

ORN

:

GREEN & YELLOW

GRN&YEL

:

GREEN

GRN

HEAT EXCHANGER

SENSOR

(TC)

THERMO SENSOR

(TA)

RECEIVING AND

INFRARED RAYS

INDICATING PARTS

MCC-861

MCC-861

1

CN25
(WH I)

1

2

3

4

5

6

7

8

9

10

11

FILE NO. SVM-05026

4. WIRING DIAGRAM

TERMINAL

BLOCK

CN01
(BLU)

BLK

1

1

BLK

2

2

CN03
(WHI)

BLK

1

1

BLK

2

2

CN13
(WHI)

BLU

1

1

2

3

4

5

6

7

8

9

10

11

BLU
BLU
BLU
BLU
BLU
BLU
BLU
BLU
BLU
WHI

1

2

2

3

3

4

4

5

5

6

6

7

7

8

8

9

9

10

10

11

11

2

CN24

FUSE

F01

T3.15A

250VAC

MAIN P.C. BOARD

WP-004

4

３

２

1

BLK W HI RED

CN23

CN21

3

CN08

3

1

2

HA

JEM-A

LINE

FILTER

R04

CN11 CN10

4

1

1

YEL

Drive ci rcuit

2

3

3

2

GRY

1

1

150°C

Fan Motor

BRW

INDOOR

UNIT

Power

supply circ uit

+12 VDC

+5 VDC

5

5

WHI

2

2

6

4

5

3

4

5

3

6

OUTDOOR

UNIT

5

CN07
(WH I)

1

1

2

2

3

3

4

4

5

5

3

1

6

1

3

BLK

RED

AC FAN MOTOR

WHI

1

1

YEL

2

2

YEL

3

3

YEL

4

4

YEL

5

5

LOUVER MOTOR

Check Item

1

2

3

4

5

OPERATION

INDICATOR

TERMINAL

BLOCK

FUSE

3.15A

DC5V

DC12V

DC325V

6

(DC310~340V)

Table 4-1-1 Simple Check for Failure Diagnosis

Diagnosis Result

Check if the OPERATION indicator goes on and off when the
main switch or breaker is turned on.
(Check the primary and secondary voltage of the transformer.)

Check the power supply v oltage betw een 1 and 2.
(Refer to the name plate.)
(Check the primary and secondary voltage of the transformer.)
Check the fluctuating voltage between 2 and 3. (15~60VDC)

Check if the fuse blows out.
(Check the R04 of the varistor.)

Check the voltage at the No. 4 pin on CN13 connector of the
infrared receiver.
(Check the transformer and the power supply circuit of the
rated voltage.)

Check the voltage at the white lead of the louver motor.
(Check the transformer and the power supply circuit of the
rated voltage.)

Check the voltage at the No. 1 pin on CN10 connector.
(Check the DB01, R05 and C03.)

Refer to the service data for the detailed failure diagnosis.

– 15 –

FILE NO. SVM-05026

4-2. Outdoor Unit

– 16 –

FILE NO. SVM-05026

5. SPECIFICATION OF ELECTRICAL PARTS

5-1. Indoor Unit

No. Parts name Type Specifications

1 Fan motor (for indoor) SKF-220-20-4A-1 AC Motor with 150°C thermo fuse
2 Thermo. sensor (TA-sensor) 10 k at 25°C 
3 AC-AC transformer (T01) TT-10 187 - 276V, 6VA
4 Microcomputer
5 Heat exchanger sensor

(TC-sensor)

6 Line filter (L01) SS11V-06270 27 µ
7 Diode (DB01) KBP06M 1.5A, 420V
8 Capacitor (C50)
9 Fuse (F01) BET 3.15A 250VAC T3.15A, 250 V

10 Regulator IC (IC08) NJM7812 12VDC, 1.5A max
11 Regulator IC (IC11) NJM7805 5VDC, 1.5A max
12 Varistor (R21, R109) 15G561K 560 V

µPD780024AGK

LXV35VB2200MJ20 2200 µ F, 35V

Ω

10 k at 25°C

Ω

H, AC 0.64A

13 Louver motor 24BYJ48 DC 12V

5-2. Outdoor Unit

No. Parts name Model name Rating

1 SC coil L01 ADR2516-0R6TB 0.6mH, 15A

(Noise filter) L03 ADR2510-020T4B 10A, 2mH

3 Reactor CH-51-Z-T L=19mH, 10A

4 Outside fan motor
5

Fan control relay

Outside air temp.

6

sensor (TO sensor)
Heat exchanger temp.

7

sensor (TE sensor)
Dischenge temp.

8

sensor (TD sensor)

9

Terminal block (6P)

Fuse

10

11

Electrolytic capacitor LLQ2G761KHUBTF 760µF, DC 400 V x 3 pieces

12

IGBT GT20J321 20A, 600

13

Compressor DA89X1F-23F 3-phases 4-poles 750W
Compressor thermo. PW-2AL OFF: 125 ± 4°C, ON: 90 ± 5°C

14

15

Rectifier

16 4-way valve coil SQ583

SWT-72

HF-240-20B-2 20W

G5NB-1A Coil DC12V Contact AC250V-1.5A

(Inverter attached) 10kΩ (25°C)

(Inverter attached) 10kΩ (25°C)

(Inverter attached) 62kΩ (20°C)

JX0-6B

For protection of switching power source 3.15A, AC250V

For protection of inverter input overcurrent 25A, AC250V

D25XB60-4001 20A, 600V

Primary side DC280V, Secondary2 DC-DC transformer
side 7.0 V x 1, 12 V x 1, 17V x 2

20A, AC250V

AC220-240V

– 17 –

6. REFRIGERANT CYCLE DIAGRAM

6-1. Refrigerant Cycle Diagram

P

Pressure measurement
Gauge attaching port
Vacuum pump connecting port

Deoxidized copper pipe

Outer dia. : 9.52mm
Thickness : 0.80mm

INDOOR UNIT

Indoor heat

exchanger

Cross flow fan

Deoxidized copper pipe

Outer dia. : 6.35mm
Thickness : 0.80mm

Sectional shape
of heat insulator

T1

Temp. measurement

FILE NO. SVM-05026

Max. :10m

Allowable height

difference : 8m

Allowable pipe length

4-way valve

Muffler

TD

Compressor
DA89X1F-23F

TS

Outdoor heat

exchanger

Split capillary

1.0x600

Temp. measurement

T2

Propeller fan

OUTDOOR UNIT

1.0x600

TE

Refrigerant amount : 0.64kg

NOTE: Gas leak check position

Refrigerant flow (Cooling)
Refrigerant flow (Heating)

Note :

• The maximum length of the pipe for this air conditioner is 10 m. The additional charging of refrigerant is
unnecessary because this air conditioner is designed with charge-less specification.

– 18 –

6-2. Operation Data

<Cooling>

FILE NO. SVM-05026

Temperature

condition (°C)

Indoor Outdoor

27/19 35/−

<Heating>

Temperature

condition (°C)

Indoor Outdoor

20/− 7/6

Standard

pressure

P (MPa)

1.1

Standard

pressure

P (MPa)

2.4

Heat exchanger

pipe temp.

T1 (°C) T2 (°C)

13.5 49

Heat exchanger

pipe temp.

T1 (°C) T2 (°C)

40 0

Indoor

fan

mode

High

Indoor

fan

mode

High

Outdoor

fan

mode

High

Outdoor

fan

mode

High

Compressor

revolution

Compressor

revolution

Note :

(1) Measure surface temperature of heat exchanger pipe around center of heat exchanger path U bent.

(Thermistor themometer)

(2) Connecting piping condition : 5m

(rps)

54

(rps)

70

− 19 −

7-1. Indoor Unit

Heat Exchanger Sensor

7. CONTROL BLOCK DIAGRAM

Indoor Unit Control Panel

M.C.U.

Functions

• Louver Control

FILE NO. SVM-05026

Operation

Display

Temperature Sensor

Infrared Rays Signal Receiver

Initiallizing Circuit

Infrared

Rays

36.7KHz

Remote

Control

From Outdoor Unit

Clock Frequency

Oscillator Circuit

Power Supply

Circuit

Noise Filter

• 3-minute Delay at Restart for Compressor

• Motor Revolution Control

• Processing

(Temperature Processing)

• Timer

• Serial Signal Communication

Louver ON/OFF Signal

Louver Driver

Serial Signal Transmitter/Receiver

Serial Signal Communication

Timer

Display

Filter Sign

Display

PRE DEF.

Sign Display

Hi Power

Sign Display

Indoor Fan

Motor

Louver Motor

REMOTE CONTROL

Infrared

Rays

Remote Control

Operation ( )

Operation Mode Selection

AUTO, COOL, DRY, HEAT, FAN ONLY

Temperature Setting
Fan Speed Selection

ON TIMER Setting

OFF TIMER Setting

Louver Auto Swing

Louver Direction Setting

ECO

Hi power

– 20 –

7-2. Outdoor Unit (Inverter Assembly)

For indoor unit

Inverter

(DC AC)

Compressor

FILE NO. SVM-05026

Over

)

5009

ter

Conver

P.C.B (MCC-

current

sensor

(AC DC)

ive

Gate dr

circuit

wer factor

High po

correction circuit

Rotor position

detect circuit

M. C. U

C. U

Relay

Relay

Fanmotor

y
4wa

Valve

Input

current

Noise

filter

sensor

220-240V 50/60Hz

∅

1

signal

– 21 –

an control

wer factor correction control

1. PWM synthesis function

2. Input current release control

3. IGBT over-current detect control

4. Outdoor f

5. High po

6.Signal communication to indoor unit M.

Outdoor air

Dischage pipe

temp. sensor

temp. sensor

Heat Exchanger

temp. sensor

8. OPERATION DESCRIPTION

FILE NO. SVM-05026

8-1. Outline of Air Conditioner Control

This air conditioner is a capacity-variable type air
conditioner. The capacity proportional control
compressor which can change the motor speed is
mounted. The indoor unit motor drive circuit is
mounted to the indoor unit. The compressor and the
inverter to control outdoor unit motor are mounted
to the outdoor unit.
The entire air conditioner is mainly controlled by the
indoor unit controller.

The indoor unit controller drives the indoor fan motor
based upon command sent from the remote control,
and transfers the operation command to the outdoor

unit controller.
The outdoor unit controller receives operation

command from the indoor unit side, and controls the
outdoor fan and the pulse modulating valve. (P.M.V)
Besides, detecting revolution position of the
compressor motor, the outdoor unit controller controls
speed of the compressor motor by controlling output
voltage of the inverter and switching timing of the
supply power (current transfer timing) so that motors
drive according to the operation command. And then,
the outdoor unit controller transfers reversely the
operating status information of the outdoor unit to
control the indoor unit controller.

As the compressor adopts four-pole brushless
DC motor, the frequency of the supply power
from inverter to compressor is two-times
cycles of the actual number of revolution.

(1) Role of indoor unit controller

The indoor unit controller judges the operation
commands from the remote controller and
assumes the following functions.

• Judgment of suction air temperature of the
indoor heat
temp. sensor (TA sensor)

• Temperature setting of the indoor heat
exchanger by using heat exchanger sensor
(TC sensor) (Prevent-freezing control)

• Louver motor control

• Indoor fan motor operation control

• LED (Light Emitting Diode) display control

• Transferring of operation command signal

(Serial signal) to the outdoor unit

• Reception of information of operation status
(Serial signal including outside temp. data) to
the outdoor unit and judgment/display of error

(2) Role of outdoor unit controller

Receiving the operation command signal (Serial
signal) from the indoor controller, the outdoor unit
performs its role.

• Compressor operation
control

• Operation control of
outdoor fan motor

• P.M.V. control

• Detection of inverter input current and current

release operation

• Over-current detection and prevention
operation to IGBT module (Compressor stop
function)

• Compressor and outdoor fan stop function
when serial signal is off (when the serial signal
does not reach the board assembly of outdoor
control by trouble of the signal system).

• Transferring of operation information (Serial
signal) from outdoor unit to indoor unit

• Detection of outdoor temperature and
operation revolution control

• Defrost control in heating operation (Temp.
measurement by outdoor heat exchanger and
control for 4-way valve and outdoor fan)

exchanger by using the indoor

Operations followed
to judgment of serial
signal from indoor
side.

− 22 −

FILE NO. SVM-05026

(3) Contents of operation command signal (Serial

signal) from indoor unit controller to outdoor unit
controller
The following three types of signals are sent from
the indoor unit controller.

•Operation mode set on the remote control

• Compressor revolution command signal

defined by indoor temperature and set tem­perature (Correction along with variation of
room
temperature and correction of indoor heat
exchanger temperature are added.)

• For these two types of signals ([Operation
mode] and [Compressor revolution]), the
outdoor unit controller monitors the input
current to the inverter, and performs the
followed operation within the range that current
does not exceed the allowable value.

• Temperature of indoor heat exchanger by
indoor heat exchanger sensor
(Minimum revolution control)

(4) Contents of operation command signal (Serial

signal) from outdoor unit controller to indoor unit
controller
The following signals are sent from the outdoor
unit controller.

• The current operation mode

• The current compressor revolution

• Outdoor temperature

• Existence of protective circuit operation

For transferring of these signals, the indoor unit
controller monitors the contents of signals, and
judges existence of trouble occurrence.
Contents of judgment are described below.

• Whether distinction of the current operation
status meets to the operation command signal

• Whether protective circuit operates
When no signal is received from the outdoor
unit controller, it is assumed as a trouble.

8-1-1. Capacity control

The cooling and heating capacity is varied by changing
compressor motor speed. The inverter changes
compressor motor speed by changing
AC 220-240 V power to DC once, and controls capac­ity by changing supply power status to the compressor
with transistor module (includes 6 transistors). The
outline of the control is as follows:

The revolution position and revolution speed of the
motor are detected by detecting winding electromotive
force of the compressor motor under operation, and
the revolution speed is changed so that the motor
drives based upon revolution speed of the operation
command by changing timing (current transfer timing)
to exchange inverter output voltage and supply power
winding.

Detection of the revolution position for controlling is
performed 12 times per 1 revolution of compressor.
The range of supply power frequency to the
compressor differs according to the operation status
(COOL, HEAT, DRY).

Table 8-1-1 Compressor revolution range

Operation Model

mode name

COOL

HEAT

8-1-2. Current release control

The outdoor main circuit control section (Inverter
assembly) detects the input current to the outdoor unit.
If the current value with compressor motor speed
instructed from indoor side exceeds the specified
value, the outdoor main circuit control section controls
compressor motor speed by reducing motor speed so
that value becomes closest to the command within the
limited value.

10NKV

Compressor

revolution (rps)

21 to 64
21 to 83

8-1-3. Power factor improvement control

Power factor improvement control is performed mainly
aiming to reduce the current on much power consump­tion of cooling/heating operation. Controlling starts
from the time when input power has reached at a
certain point. To be concrete, IGBT of the power factor
improvement circuit is used, and the power factor is
improved by keeping IGBT on for an arbitrary period to
widen electro-angle of the input current.

– 23 −