7MBP75RTJ060_技术文档

Quality is our message

FUJI IGBT–IPM

APPLICATION MANUAL

Sep. 2004

REH983a

CONTENTS

Chapter 1 Features

1. GBT-IPMs Characteristics........................................................................1-2

2. IPM Characteristics by Series ..................................................................1-4

3. Definition of Type Name and Lot No.........................................................1-6

4. Lineup ......................................................................................................1-7

5. Outline Drawings......................................................................................1-8

Chapter 2 Description of Terminal Symbols and Terminology

1. Description of Terminal Symbols ..............................................................2-2

2. Description of Terminology.......................................................................2-3

Chapter 3 Description of Functions

1. Function Tables ........................................................................................3-2

2. Function Descriptions...............................................................................3-4

3. Truth Tables............................................................................................3-11

4. IPM Block Diagrams...............................................................................3-13

5. Timing Charts.........................................................................................3-21

Chapter 4 Examples of Application Circuits

1. Examples of Application Circuits ..............................................................4-2

2. Precautions ..............................................................................................4-7

3. Photocoupler and Peripheral Circuits.....................................................4-10

4. Connectors............................................................................................. 4-11

Chapter 5 Cooling Design

1. Cooler (Heat Sink) Selection Method.......................................................5-2

2. Notes on Heat Sink Selection...................................................................5-2

Chapter 6 Cautions on Use

1. Main Power Source..................................................................................6-2

2. Control Power Source ..............................................................................6-3

3. Protection Functions.................................................................................6-4

4. Power Cycling Capability..........................................................................6-6

5. Other ........................................................................................................6-6

Chapter 7 Trouble Shooting

1. Trouble Shooting......................................................................................7-2

2. Fault Analysis Diagrams...........................................................................7-2

3. Alarm Cause Analysis Diagram................................................................7-8

Quality is our message

Chapter 1

Features

Contents

Page

1 GBT-IPMs Characteristics .................................................................................1-2

2 IPM Characteristics by Series ...........................................................................1-4

3 Definition of Type Name and Lot No..................................................................1-6

4 Lineup................................................................................................................1-7

5 Outline Drawings ...............................................................................................1-8

1–1

Chapter 1 Features

1

GBT-IPMs Characteristics

An intelligent power module (IPM) has the following characteristics when compared with a combination

of IGBT modules and drive circuits.

1.1 Built-in drive circuit

• IGBT gate drives operate under optimal conditions.

• Since the wiring length between the internal drive circuit and IGBT is short and the impedance of the

drive circuit is low, no reverse bias DC source is required.

• The R-series IPM (R-IPM) devices require four control power sources, one source on the lower arm

side, and three individual sources on the upper arm side with proper circuit isolation.

1.2 Built-in protection circuits

• The following built-in protection circuits are included in the R-IPM devices:

(OC): Overcurrent protection

(SC): Short-circuit protection

(UV): Undervoltage protection for control power source

(OH): Overheating protection

(ALM): External alarm output

• The OC and SC protection circuits provide protection against IGBT damage caused by overcurrent or

load short-circuits. These circuits monitor the collector current using detection elements incorporated in

each IGBT and thus can minimize the possibility of severe damage to the IGBT. They also protect

against arm short-circuits.^*1

• The UV protection circuit is in all of the IGBT drive circuits. This circuit monitors the Vcc supply voltage

level against the IGBT drive Vin.

• The OH protection circuit protects the IGBT and FWD from overheating. It also monitors the insulating

substrate’s temperature with temperature detection elements installed on the insulating substrates

inside the IPM.

(Case temperature overheating protection: TcOH)^*2

1-2

Chapter 1 Features

• Additionally, each IGBT chip contains a temperature detection element on the IGBT die, which allows

the OH to act rapidly when abnormally high chip temperatures are detected. (Junction temperature

overheating protection: TjOH)

• The ALM circuit outputs an alarm signal to outside of the IPM, making it possible to shutdown the

system reliably by outputting the alarm signal to the microcontroller which controls IPM when the circuit

detects an abnormal condition (specified above). ^*2

^*1The N-line shunt resistance method is used for overcurrent detection of small-capacity types.

^*2Refer to Chapter 3 “Description of Functions” for the protective functions of each IPM.

1.3 Built-in brake circuit (7 in 1 IPM)

• For a motor control inverter application, a brake circuit can be built to protect bus overvoltage by just

adding a power dissipating resistor.

• The drive circuits and protection circuits are included in the brake IGBT in the same way as inverter

IGBTs.

1-3

Chapter 1 Features

2

IPM Characteristics by Series

2.1 R-IPM, R-IPM3 series

2.1.1 Small-capacity types

A lineup of small-capacity types with 15 to 30 A for 600 V systems and 15 A for 1200 V systems is

available. (P617, P619 package)

• P617 package products are a type without a copper base, while P619 package products are a type with

a copper base, which further improves the heat radiation ability.

• The control input terminals have a standard pitch of 2.54 mm.

• The shape of the main terminals is the Faston shape, and as the height is the same as that of the

control input terminals, connection by the same printed boards is possible with the soldering method as

well as with the connector method.

• By improvement of the trade-off between Vce(sat) and switching loss, the total loss has been improved.

• The chip is protected from abnormal heating by IGBT chip overheating protection.

2.1.2 Medium-capacity types (alarm output only for the lower arm)

A lineup of medium-capacity types with 50 to 150 A for 600 V systems and 25 to 75 A for 1200 V

systems is available. (P610, P611 package)

• The control input terminals have a standard pitch of 2.54 mm, they are arranged in one line, and

connection is possible with one connector for general use. A guide pin makes insertion of the connector

for the printed board easy.

• The main power source inputs (P, N), the brake output (B), and the output terminals (U, V, W) are

arranged close to each other, and the main wiring is a simple package construction.

• As the main terminals are M5 screws, large currents can be connected securely.

• The screw diameter for connection to the heat sink is M5, the same as for the main terminals.

• As all electrical connections are made by screws or connectors, soldering is not required and removal is

easy.

• By improvement of the trade-off between Vce(sat) and switching loss, the total loss has been improved.

• The chip is protected from abnormal heating by IGBT chip overheating protection.^*3

^*3There is no alarm output from the upper arm side.

2.1.3 Medium-capacity types (with upper arm alarm output function)

A lineup of medium-capacity types with 50 to 150 A for 600 V systems and 25 to 75 A for 1200 V

systems is available. (P621 package)

• OC, SC, UV, and TjOH alarm signals can be output from the upper arm. This allows secure protection

against trouble from ground faults, etc.^*4

• As the main terminals are M5 screws, large currents can be connected securely.

• The screw diameter for connection to the heat sink is M5, the same as for the main terminals.

1-4

Chapter 1 Features

• As all electrical connections are made by screws or connectors, soldering is not required and removal is

easy.

• By improvement of the trade-off between Vce(sat) and switching loss, the total loss has been improved.

• The chip is protected from abnormal heating by IGBT chip overheating protection.

^*4The TcOH alarm is output only from the lower arm.

2.1.4 Large-capacity types (alarm output only for the lower arm)

A lineup of large-capacity types with 200 to 300 A for 600 V systems and 100 to 150 A for 1200 V

systems is available. (P612 package)

• The layout of the control input terminals is the same as for the medium-capacity standard package, and

correspondence is possible with one connector type.

• The main power source inputs (P, N), the brake output (B), and the output terminals (U, V, W) are

arranged close to each other, and the main wiring is a simple package construction.

• As the main terminals are M5 screws, large currents can be connected securely.

• The screw diameter for connection to the heat sink is M5, the same as for the main terminals.

• As all electrical connections are made by screws or connectors, soldering is not required and removal is

easy.

• By improvement of the trade-off between Vce(sat) and switching loss, the total loss has been improved.

• The chip is protected from abnormal heating by IGBT chip overheating protection.^*5

^*5There is no alarm output from the upper arm side.

2.2 Econo IPM series

The Econo IPM series is a lineup with 50 to 150 A for 600 V systems and 25 to 75 A for 1200 V systems.

(P622 package)

• In comparison with the medium-capacity types, the mounting area has been reduced by approximately

30% and the mass has been reduced by approximately 40%, contributing to reduction of the device size.

• As the height is the same as that of Econo DIMs (Econo Diode Modules), connection is possible with

the same printed circuit boards.

• OC, SC, UV, and TjOH alarm signals can be output from the upper arm. This makes secure protection

against trouble from ground faults etc. possible.

• The chip is protected from abnormal heating by IGBT chip overheating protection.

1-5

Chapter 1 Features

3

Definition of Type Name and Lot No.

• Type name

7 MBP 50 RT A 060 -01

Additional model number (if necessary)

機種の追い番(無い場合もあります。)

Voltage rating

耐圧

060: 600V

060: 600 V

120: 1200V

600 V

120: 1200 V

シリーズの追番

Additional number of series

シリーズ名

Series name

R: R-IPM

RT: R-IPM3

RT： R-IPM3

^TT^EE^::^EE^cocⁿo^on^Io^PMIPM

Inverter IGBT current rating

インバータ部電流定格

50： 50A

50: 50 A

IGBT-IPM を表す

Indicates IGBT-IPM

主素子数

Number of main elements

7: ブレーキ内蔵

7-chip circuit with built-in brake

6: ブレーキ無し

6-chip circuit without dynamic brake

• Lot No.

4 1 01

追番(01～99）

Additional number (01 to 99)

生産月

Month of production

1: 1月

1: Jan.

9: Sep.

9: 9月

0: Oct.

O: 10月

N: Nov.

N: 11月

D: Dec.

D: 12月

生産年

Year of production

4：2004年

4: 2004

Type name

形式

Lot No.

ロット№

7M B P 50R T A 060

50A 600V Japan O

4101

1-6

Chapter 1 Features

4

Lineup

600 V system, 15 to 75 A

15A

20A

30A

50A

75A

R-IPM

6MBP15RH060

6MBP20RH060

6MBP30RH060

6MBP50RA060

7MBP50RA060

6MBP75RA060

7MBP75RA060

R-IPM3

6MBP20RTA060

6MBP50RTB060

7MBP50RTB060

6MBP50RTJ060

7MBP50RTJ060

6MBP75RTB060

7MBP75RTB060

6MBP75RTJ060

7MBP75RTJ060

−

Econo

IPM

6MBP50TEA060

7MBP50TEA060

6MBP75TEA060

7MBP75TEA060

−

600 V system, 100 to 300 A

100A

150A

200A

300A

R-IPM

6MBP100RA060

7MBP100RA060

6MBP150RA060

7MBP150RA060

6MBP200RA060

6MBP300RA060

7MBP200RA060

7MBP300RA060

R-IPM3

6MBP100RTB060

7MBP100RTB060

6MBP100RTJ060

7MBP100RTJ060

6MBP150RTB060

7MBP150RTB060

6MBP150RTJ060

7MBP150RTJ060

−

Econo

IPM

6MBP100TEA060

7MBP100TEA060

6MBP150TEA060

7MBP150TEA060

−

1200 V system

15A

25A

50A

75A

100A

150A

R-IPM

6MBP15RA120

6MBP25RA120

7MBP25RA120

6MBP25RJ120

7MBP25RJ120

6MBP50RA120

7MBP50RA120

6MBP50RJ120

7MBP50RJ120

6MBP75RA120

7MBP75RA120

6MBP75RJ120

7MBP75RJ120

6MBP100RA120

7MBP100RA120

6MBP150RA120

7MBP150RA120

Econo

IPM

6MBP25TEA120

7MBP25TEA120

6MBP50TEA120

7 MBP50TEA120

6MBP75TEA120

7MBP75TEA120

−

1-7

Chapter 1 Features

5

Outline Drawings

Fig. 1-1 Outline Drawing (P617)

Type name: 6MBP15RH060, 6MBP20RH060, 6MBP30RH060

1-8

Chapter 1 Features

1

10

4

7

15

Ｐ

Ｕ

Ｖ

Ｗ

Ｎ１Ｎ２

Fig. 1-2 Outline Drawing (P619)

Type name: 6MBP20RTA060, 6MBP15RA120

1-9

Chapter 1 Features

Fig. 1-3 Outline Drawing (P610)

Type name: 6MBP50RA060, 6MBP75RA060, 6MBP50RTB060, 6MBP75RTB060, 6MBP25RA120

7MBP50RA060, 7MBP75RA060, 7MBP50RTB060, 7 MBP75RTB060, 7MBP25RA120

1-10

Chapter 1 Features

Fig. 1-4 Outline Drawing (P611)

Type name: 6MBP100RA060, 6MBP150RA060, 6MBP100RTB060, 6MBP150RTB060, 6MBP50RA120, 6MBP75RA120

7MBP100RA060, 7MBP150RA060, 7MBP100RTB060, 7MBP150RTB060, 7MBP50RA120, 7MBP75RA120

1-11

Chapter 1 Features

Fig. 1-5 Outline Drawing (P612)

Type name: 6MBP200RA060, 6MBP300RA060, 6MBP100RA120, 6MBP150RA120

7MBP200RA060, 7MBP300RA060, 7MBP100RA120, 7MBP150RA120

1-12

Chapter 1 Features

Fig. 1-6 Outline Drawing (P621)

Type name: 6MBP50RTJ060, 6MBP75RTJ060, 6MBP100RTJ060, 6MBP150RTJ060, 6MBP25RJ120, 6MBP50RJ120, 6MBP75RJ120

7MBP50RTJ060, 7MBP75RTJ060, 7MBP100RTJ060, 7MBP150RTJ060, 7MBP25RJ120, 7MBP50RJ120, 7MBP75RJ120

1-13

Chapter 1 Features

Fig. 1-7 Outline Drawing (P622)

Type name: 6MBP50TEA060, 6MBP75TEA060, 6MBP100TEA060, 6MBP150TEA060

6MBP25TEA120, 6MBP50TEA120, 6MBP75TEA120

7MBP50TEA060, 7MBP75TEA060, 7MBP100TEA060, 7MBP150TEA060

7MBP25TEA120, 7MBP50TEA120, 7MBP75TEA120

1-14

Quality is our message

Chapter 2

Description of Terminal Symbols and

Terminology

Contents

Page

1. Description of Terminal Symbols ......................................................................2-2

2. Description of Terminology ...............................................................................2-3

2–1

Chapter 2 Description of Terminal Symbols and Terminology

1

Description of Terminal Symbols

Main terminals

Terminal Symbol

Description

Main power source Vd input terminal for the inverter bridge.

P: + side, N: − side

P

N

Brake output terminal: terminal to connect the resistor for regenerative operation

B

declaration

3-phase inverter output terminal

U

V

W

Main power source Vd "negative(-)" input terminal after rectification converter

smoothing of the inverter unit (P617, 619)

N2

Terminal for external connection of resistance when the OC level is to be changed

(P617, 619)

N1

Control terminals

Terminal P610, P611

P617

P619

<1>

P621

P622

<1>

Description

Symbol

GND U

Vcc U

P612

Control power source Vcc input in the upper arm U phase

Vcc U: + side, GND U: − side

<1>

<3>

<2>

<3>

<4>

Vin U

<2>

<3>

Control signal input in the upper arm U phase

Upper arm U-phase alarm output when the protection

circuits are operating

ALM U

<2>

−

Control power source Vcc input in the upper arm V phase

Vcc V: + side, GND V: − side

GND V

Vcc V

Vin V

<4>

<6>

<5>

<4>

<6>

<5>

<8>

<7>

Control signal input in the upper arm V phase

Upper arm V-phase alarm output when the protection

circuits are operating

ALM V

<6>

−

Control power source Vcc input in the upper arm W phase

Vcc W : + side, GND W: − side

GND W

Vcc W

Vin W

<7>

<9>

<8>

<7>

<9>

<8>

<9>

<12>

<11>

Control signal input in the upper arm W phase

Upper arm W-phase alarm output when the protection

circuits are operating

ALM W

<10>

−

Control power source Vcc input in the lower arm common

Vcc: + side, GND: − side

GND

Vcc

Vin X

Vin Y

Vin Z

Vin DB

<10>

<11>

<13>

<14>

<15>

<12>

<10>

<11>

<12>

<13>

<14>

−

<13>

<14>

<16>

<17>

<18>

<15>

Control signal input in the lower arm X phase

Control signal input in the lower arm Y phase

Control signal input in the lower arm Z phase

Control signal input in the lower arm brake phase

Lower arm alarm output when the protection circuits are

operating

ALM

<16>

<15>

<19>

2-2

Chapter 2 Description of Terminal Symbols and Terminology

2

Description of Terminology

1. Absolute Maximum Ratings

Term

Symbol

Description

Bus voltage

V_DC

DC voltage that can be applied between PN terminals

DC Bus voltage

V_DC

Peak value of the surge voltage that can be applied between PN

(surge)

terminals in switching

DC Bus voltage

(short circuit)

DC source voltage between PN terminals that can be protected from

short circuits/overcurrent

V_SC

Maximum collector-emitter voltage of the built-in IGBT chip and

repeated peak reverse voltage of the FWD chip (only the IGBT for the

brake)

Collector-emitter

Voltage

V_CES

Reverse voltage

Collector current

FRD forward Current

V_R

I_C

I_CP

–I_C

I_F

Repeated peak reverse voltage of the FWD chip in the brake section

Maximum DC collector current for the IGBT chip

Maximum DC pulse collector current for the IGBT chip

Maximum DC forward current for the FWD chip

Maximum DC forward current for the FWD chip in the brake section

Maximum power dissipation for one IGBT element

Collector power

Dissipation

P_C

Power dissipation for Tj to become 150°C at Tc = 25°C or power

dissipated in collector so that Tj becomes 150°C at Tc = 25°C

Control power source

voltage

Input voltage

Input current

Alarm signal voltage

Alarm signal current

Chip junction

Temperature

Operating case

temperature

V_CC

Voltage that can be applied between GND and each Vcc terminal

Vin

Iin

V_ALM

I_ALM

Voltage that can be applied between GND and each Vin terminal

Current that flows between GND and each Vin terminal

Voltage that can be applied between GND and ALM terminal

Current that flows between GND and ALM terminal

Maximum junction temperature of the IGBT and FWD chips during

Tj

continuous operation

Range of case temperature for electrical operation (Fig. 1 shows the

measuring point of the case temperature Tc)

Range of ambient temperature for storage or transportation, when

there is no electrical load

Topr

T_stg

Storage temperature

Maximum effective value of the sine-wave voltage between the

terminals and the heat sink, when all terminals are shorted

simultaneously

Isolating voltage

Viso

Screw

Max. torque for connection of terminal and external wire with the

specified screw

Terminal

torque

−

Max. torque when mounting the element to the heat sink with the

specified screw

Mounting

2-3

Chapter 2 Description of Terminal Symbols and Terminology

2. Electrical Characteristics

2.1 Main Circuit

Term

Symbol

I_CES

Description

Collector-emitter cutoff

Collector current when a specified voltage is applied between the

collector and emitter of an IGBT with all input signals H (= Vz)

Collector-emitter voltage at a specified collector current when the

input signal of only the elements to be measured is L (= 0V) and the

inputs of all other elements are H (= Vz)

current

Collector-emitter

V

_CE(sat)

saturation voltage

Forward voltage at a specified forward current with all input signals H

(= Vz)

Diode forward voltage

Turn-on time

V_F

The time from the input signal dropping below the threshold value until the

collector current becomes 90% of the rating. See Fig. 2-3.

The time from the input signal rising above the threshold value until the

collector current becomes 10% of the rating. See Fig. 2-3.

The time from the collector current becoming 90% at the time of IGBT turn-off

until the tangent to the decreasing current becomes 10%. See Fig. 2-3.

The time required for the reverse recovery current of the built-in diode to

disappear. See Fig. 2-3.

ton

toff

tf

Turn-off time

Fall time

Reverse recovery time

trr

2.2 Control Circuits

Term

Symbol

Description

Current flowing between control power source Vcc and GND on the P-side

(upper arm side)

Iccp

Iccn

Control power source

consumption current

Current flowing between control power source Vcc and GND on the N-side

(lower arm side)

Vinth (on) Control signal voltage when IGBT changes from OFF to ON

Vinth (off) Control signal voltage when IGBT changes from ON to OFF

Input signal threshold

voltage

Voltage clamped by zener diode connected between GND and each

Input zenor voltage

Vz

Vin when the control signal is OFF

Period in which an alarm continues to be output (ALM) from the ALM

Signal hold time

t_ALM

terminal after the N-side protection function is actuated

Limiting resistor for

alarm

Built-in resistance limiting the primary current of the photocoupler for

R_ALM

ALM output

Current detection shunt

resistance

R1

Resistance value of the IPM built-in shunt resistor (P617, P619)

2.3 Protection Circuits

Term

Symbol

I_OC

Description

Overcurrent protective

IGBT collector current at which the overcurrent protection (OC) works

operation current

Overcurrent cut off time

t_DOC

tsc

Shown in Fig. 2-1

Shown in Fig. 2-2

Short-circuit protection

delay time

Chip overheating

protection temperature

Chip overheating

protection hysteresis

Case overheating

protection temperature

Case overheating

protection hysteresis

Under voltage protection

level

Tripping temperature at which the IGBT chip junction temperature Tj

overheats and IGBT soft shutdown is performed

TjoH

TjH

Drop temperature required for output stop resetting after protection operation

Tripping temperature at which the IGBT performs soft shutdown when the

case temperature Tc shows overheating

TcOH

TcH

V_UV

Drop temperature required for output stop resetting after protection operation

Tripping voltage at which the IGBT performs soft shutdown when the control

power source voltage Vcc drops

Control power source

undervoltage protection

hysteresis

Recovery voltage required for output stop resetting after protection

operation

V_H

2-4

Chapter 2 Description of Terminal Symbols and Terminology

3. Thermal Characteristics

Term

Symbol

Description

Chip-case thermal

Rth (j-c)

Chip-case thermal resistance of IGBT or diode

resistance

Chip-fin thermal

resistance

Rth (c-f)

Thermal resistance between the case and heat sink, when mounted

on a heat sink at the recommended torque using the thermal

compound

Case temperature

Tc

IPM case temperature (temperature of the copper plate directly under

the IGBT or the diode)

4. Noise Tolerance

Term

Common mode noise

Electric surge

Symbol

Description

Common mode noise tolerance in our test circuit

Electric surge tolerance in our test circuit

−

5. Other

Term

Weight

Symbol

Wt

Description

Weight of IPM

Range of control signal frequencies for input to the control signal

Switching frequency

fsw

input terminal

Reverse recovery

current

Irr

Shown in Fig. 2-3

Reverse bias safe

operation area

Switching loss

Area of the current and voltage in which IGBT can be cut off under

specified conditions during turn-off

IGBT switching loss during turn-on

IGBT switching loss during turn-off

FWD switching loss during reverse recovery

RBSOA

Eon

Eoff

Err

Ioc

Ic

IALM

t

doc

Fig. 2-1 Overcurrent Protection Delay Time (tdoc)

2-5

Chapter 2 Description of Terminal Symbols and Terminology

tsc

Isc

Ic

IALM

Fig. 2-2 Short-circuit Protection Delay Time (tsc)

Input signal

(Vin)

Vinth (on)

Vinth (off)

trr

Irr

90%

10%

90%

Collector current

(Ic)

tf

toff

ton

Fig. 2-3 Switching Time

2-6

Quality is our message

Chapter 3

Description of Functions

Contents

Page

1. Function Tables ................................................................................................3-2

2. Function Descriptions.......................................................................................3-4

3. Truth Tables.....................................................................................................3-11

4. IPM Block Diagrams........................................................................................3-13

5. Timing Charts ..................................................................................................3-21

3–1

Chapter 3 Descriptions of Functions

1

Function Tables

The functions built into the IPM are shown in Tables 3-1 to 3-3.

Table 3-1 IPM Built-in Functions (R-IPM)

600 V system

Built-in Functions

Element

Number

Common for Upper and

Upper Arm

Lower Arm

Model

Package

Dr ^LU^owV^{er Arm}TjOH

OC ALM

OC

ALM

TcOH

6MBP15RH060

6MBP20RH060

6MBP30RH060

6MBP50RA060

6MBP75RA060

6MBP100RA060

6MBP150RA060

6MBP200RA060

6MBP300RA060

7MBP50RA060

7MBP75RA060

7MBP100RA060

7MBP150RA060

7MBP200RA060

7MBP300RA060

P617

P610

P611

P612

P610

P611

P612

√

−

√

−

√

−

√

6 in 1

7 in 1

1200 V system

Built-in Functions

Element

Number

Common for Upper and

Upper Arm

Lower Arm

Model

Package

Dr ^LU^owV^{er Arm}TjOH

OC ALM

OC

ALM

TcOH

6MBP15RA120

6MBP25RA120

6MBP50RA120

6MBP75RA120

6MBP100RA120

6MBP150RA120

7MBP25RA120

7MBP50RA120

7MBP75RA120

7MBP100RA120

7MBP150RA120

6MBP25RJ120

6MBP50RJ120

6MBP75RJ120

7MBP25RJ120

7MBP50RJ120

7MBP75RJ120

P619

P610

P611

P612

P610

P611

P612

P621

√

−

√

−

√

−

√

6 in 1

7 in 1

6 in 1

7 in 1

Dr: IGBT drive circuit, UV: Control power source undervoltage protection, TjOH: Element overheating protection, OC: Overcurrent protection,

ALM: Alarm output, TcOH: Case overheating protection

3-2

Chapter 3 Descriptions of Functions

Table 3-2 IPM Built-in Functions (R-IPM3)

600 V system

Built-in Functions

Element

Number

Common for Upper and

Upper Arm

Lower Arm

Model

Package

Dr ^LU^owV^{er Arm}TjOH

OC ALM

OC

ALM

TcOH

6MBP20RTA060

6MBP50RTB060

6MBP75RTB060

6MBP100RTB060

6MBP150RTB060

7MBP50RTB060

7MBP75RTB060

7MBP100RTB060

7MBP150RTB060

6MBP50RTJ060

6MBP75RTJ060

6MBP100RTJ060

6MBP150RTJ060

7MBP50RTJ060

7MBP75RTJ060

7MBP100RTJ060

7MBP150RTJ060

P619

P610

P611

P610

P611

P621

√

−

√

−

√

−

√

6 in 1

7 in 1

6 in 1

7 in 1

Dr: IGBT drive circuit, UV: Control power source undervoltage protection, TjOH: Element overheating protection, OC: Overcurrent protection,

LM: Alarm output, TcOH: Case overheating protection

3-3

Chapter 3 Descriptions of Functions

Table 3-3 IPM Built-in Functions (Econo IPM)

600 V system

Built-in Functions

Element

Number

Common for Upper and

Upper Arm

Lower Arm

Model

Package

Dr ^LU^owV^{er Arm}TjOH

OC ALM

OC

ALM

TcOH

6MBP50TEA060

6MBP75TEA060

6MBP100TEA060

6MBP150TEA060

7MBP50TEA060

7MBP75TEA060

7MBP100TEA060

7MBP150TEA060

P622

√

−

6 in 1

7 in 1

1200 V system

Built-in Functions

Element

Number

Common for Upper and

Upper Arm

Lower Arm

Model

Package

Dr ^LU^owV^{er Arm}TjOH

OC ALM

OC

ALM

TcOH

6MBP25TEA120

6MBP50TEA120

6MBP75TEA120

7MBP25TEA120

7MBP50TEA120

7MBP75TEA120

P622

√

−

6 in 1

7 in 1

Dr: IGBT drive circuit, UV: Control power source undervoltage protection,

ALM: Alarm output, TcOH: Case overheating protection

TjOH: Element overheating protection, OC: Overcurrent protection,

2

Function Descriptions

2.1 IGBT, FWD for 3-phase inverters

As shown in Fig. 3-1, IGBT and FWD for 3-phase inverters are built in, and a 3-phase bridge circuit is

formed inside the IPM. The main circuit is completed by connecting the main power source to the P and N

terminals and the 3-phase output lines to the U, V, and W terminals. Connect a snubber circuit to suppress

the surge voltages.

2.2 IGBT, FWD for brake

As shown in Fig. 3-1, IGBT and FWD for brake are built in, and an IGBT collector is connected internally

to the B terminal. By controlling the brake IGBT through connection of brake resistance between the

terminals P and B, the regeneration energy can be dissipated while decelerating to suppress the rise of

voltage between the P and N terminals.

3-4

Chapter 3 Descriptions of Functions

P-side

PWM input

IPM

Pre-Driver

P

B

U

V

W

N

Pre-D river

Brake

input

N-side

PWM input

Alarm

output

Fig. 3-1 3-Phase Inverter Application Model (in Case of 7MBP150RTB060)

2.3 IGBT drive function

Fig. 3-2 shows the pre-driver block diagram. As the IPM incorporates an IGBT drive function, the IGBT

can be driven without designing a gate resistance value by connecting the photocoupler output to the IPM.

The features of this drive function are introduced below.

• Independent gate resistance control

A special turn-on/turn-off Rg not using any exclusive gate resistance Rg is built in. With this, the dv/dt

of turn-on and turn-off can be controlled individually, so that the merits of the element are fully

demonstrated (Turn on/Normal Shutdown).

• Soft shutdown

During an overcurrent or other abnormality, the gate voltage is lowered softly and gently to prevent

element destruction by surge voltage (Soft Shutdown).

• Errorneous ON prevention

Since a circuit is set up to ground the gate electrode with low impedance while OFF, erroneous ON

caused by the rise of VGE due to noise can be prevented (Off Hold).

3-5

Chapter 3 Descriptions of Functions

• A reverse bias power source is not required.

As the IPM has a short wiring between the drive circuit and the IGBT, the wiring impedance is small,

making driving without reverse bias possible.

• Alarm latch

Alarms have a latch period of approximately 2 ms, and the IGBT does not operate even when an On-

signal enters during the latch period. In addition, as the alarms for each phase, including brake, on the

lower arm side are connected mutually, all IGBTs on the lower arm side are stopped for the latch period

when a protection operation is performed on the lower arm side.

3-6

Chapter 3 Descriptions of Functions

VccU

VinU

VinV

VinW

(Same circuit as X-phase)

GNDU

VccV

(Same circuit as X-phase)

GNDV

VccW

GNDW

Vcc

in

VinX

U

Turn on

IGBT

8V

gate

Gate Voltage

Off Hold

Vcc

Normal Shutdown

alarm

Soft Shutdown

N

Vcc

<1>

TjH

Filter

1 ms

Filter

5 us

TjOH

OC

UV

Q

S

R

20°C

<2>

Delay

2ms

Vcc

<3>

Filter

5 us

VH

0.5 V

GND

Pre-driver for X-phase IGBT

Note: Delay time and hysteresis are typical values.

(Same circuit as X-phase)

VinY

VinZ

(Same circuit as X-phase)

VinDB

Tc overheating protection circuit

Vcc

<4>

ALM

TcH

Filter

1 ms

RALM

TcOH

Q

S

R

20°C

GND

Delay

2 ms

Fig. 3-2 IPM Function Block (Representative Model: 7MBP150RTB060)

3-7

Chapter 3 Descriptions of Functions

2.4 Overcurrent protection function (OC)

Two detection methods are used, the sense IGBT method and the shunt resistance method.

(1) Sense IGBT method

Models: P610/P611/P612/P621/P622

• The main current flowing in the IGBT is detected by taking the sense current flowing in the current

sense IGBT inside the IGBT chip into the control circuit. The sense current is extremely small in

comparison with the main current, so that the detection loss can be kept minimal in comparison with the

shunt resistance method.

• When the overcurrent protection Ioc level is exceeded for a duration of approximately 5 µs (tdoc), the

IGBT goes through a soft shutdown. As a detection filter is installed, faulty operations caused by

instantaneous overcurrents or noise can be prevented.

• When after approximately 2 ms the level drops below Ioc and the input signal is OFF, the alarm is

released.

(2) Shunt resistance method

Models: P617/P619

• Overcurrent protection is performed by detecting the voltage at both ends of the current detection shunt

resistance R1, connected to the DC bus bar line N. When the overcurrent detection level Ioc is

exceeded for a duration of approximately 5 µs (tdoc), the IGBT goes through a soft shutdown. As a

detection filter is installed, faulty operations caused by instantaneous overcurrents or noise can be

prevented.

• When after approximately 2 ms the level drops below Ioc and if the input signal is OFF, the alarm is

released.

2.5 Short-circuit protection function (SC)

The SC protection function always operates with the OC protection function to suppress the peak

current when a load or arm is shorted.

2.6 Undervoltage protection (UV)

• The UV protection function performs soft shutdown of the IGBT when the control source voltage (Vcc)

continuously drops below VUV for approximately 5 µs.

• As the hysteresis VH is provided, the alarm is released if Vcc recovers to VUV + VH or more after

approximately 2 ms and the input signal is OFF.

2.7 Case temperature overheating protection function (TcOH)

• The TcOH protection function detects the insulating substrate temperature with the temperature

detection elements set up on the same ceramic substrate as that on which the power chips (IGBT,

FWD) are set up and performs soft shutdown of the IGBT when the detected temperature exceeds the

protection level TcOH continuously for approximately 1 ms.

• As the hysteresis TcH is provided, the alarm is released if Tc drops below TcOH-TcH after approximately

2 ms.

• The TcOH detection positions are shown in Fig.3-3 to Fig.3-6.

3-8

Chapter 3 Descriptions of Functions

Fig. 3-3 TcOH Detection Position (P610)

Fig. 3-4 TcOH Detection Position (P611)

3-9

Chapter 3 Descriptions of Functions

Fig. 3-5 TcOH Detection Position (P612)

Fig. 3-6 TcOH Detection Position (P621)

3-10

Chapter 3 Descriptions of Functions

2.8 Chip temperature overheating protection function (TjOH)

• The TjOH protection function detects the IGBT chip temperature with the temperature detection

elements set up on all IGBT chips and performs soft shutdown of the IGBT when the detected

temperature exceeds the protection level (TjOH) continuously for approximately 1 ms or more.

• As the hysteresis TjH is provided, the alarm is released if Tj drops below TjOH-TjH after approximately 2

ms and the input signal is OFF.

2.9 Alarm output function (ALM)

• When a protection function operates, the alarm output terminal becomes conductive against each

reference potential GND. With open collector output, a function for direct drive of the photocoupler is

provided, and a 1.5 kΩ series resistor is built in.

• When a protection function operates, the alarm signal is output continuously for approximately 2 ms

(tALM). The alarm is released when the alarm cause has been removed, tALM has elapsed, and the

input signal is OFF. When the cause is TcOH, the alarm is released regardless of the input signal.

• As the alarm terminals of the drive circuit on the lower arm side are connected mutually, all IGBTs on

the lower arm side, including the brake, are stopped when any one of the IGBTs outputs an alarm.

3

Truth Tables

The truth tables when a fault occurs are shown in Tables 3-4 to 3-7.

Table 3-4 Truth Table (P617, P619)

IGBT

Cause of

Fault

Alarm Output

Low Side

U-phase

V-phase

W-phase

Low Side

UV

OFF

*

High

Low

High side

U-phase

TjOH

UV

OFF

*

OFF

*

High side

V-phase

TjOH

UV

OFF

*

OFF

*

High side

W-phase

TjOH

OC

OFF

*

OFF

Low side

UV

TjOH

* Depends on input logic

3-11

Chapter 3 Descriptions of Functions

Table 3-5 Truth Table (P610, P611, P612)

Cause of

IGBT

Alarm Output

Low Side

High

Fault

U-phase

V-phase

W-phase

Low Side

OC

UV

OFF

*

High side

U-phase

OFF

*

High

TjOH

OC

*

High

*

OFF

*

High

High side

V-phase

UV

OFF

*

High

TjOH

OC

OFF

*

High

*

OFF

*

High

High side

W-phase

UV

OFF

*

High

TjOH

OC

OFF

*

High

*

OFF

Low

UV

Low

Low side

TjOH

TcOH

Low

* Depends on input logic

Table 3-6 Truth Table (P621)

IGBT

Alarm Output

Cause of

Fault

U-phase

V-phase

W-phase

Low Side

ALMU

ALMV

ALMW

ALM

OC

UV

OFF

*

Low

High

Low

High

Low

High

Low

High side

U-phase

OFF

*

TjOH

OC

OFF

*

OFF

*

High side

V-phase

UV

OFF

*

TjOH

OC

OFF

*

OFF

*

High side

W-phase

UV

OFF

*

TjOH

OC

OFF

*

OFF

UV

Low side

TjOH

TcOH

* Depends on input logic

Table 3-7 Truth Table (P622)

IGBT

Alarm Output

ALMV ALMW

Cause of

Fault

U-phase

V-phase

W-phase

Low Side

ALMU

ALM

OC

OFF

*

Low

High

Low

High

Low

High

Low

High side

U-phase

UV

OFF

*

TjOH

OC

OFF

*

OFF

*

High side

V-phase

UV

OFF

*

TjOH

OC

OFF

*

OFF

*

High side

W-phase

UV

*

TjOH

OC

*

OFF

Low side

UV

*

TjOH

* Depends on input logic

3-12

Chapter 3 Descriptions of Functions

4

IPM Block Diagrams

The IPM block diagrams are shown in Fig. 3-7 to Fig. 3-14.

VinU

Pre-driver 1

8V

GNDU

U

V

VccV

VinV

GNDV

VccW

VinW

GNDW

Vcc

W

VinX

VinY

Pre-driver 2

VinZ

ALM

N1

R1

N2

GND

Fig. 3-7 IPM Block Diagram (P617)

3-13

Chapter 3 Descriptions of Functions

VinU

Pre-driver 1

8V

GNDU

VccV

U

V

VinV

GNDV

VccW

VinW

GNDW

Vcc

W

VinX

VinY

VinZ

ALM

Pre-driver 2

1.5k

N1

R1

N2

GND

Fig. 3-8 IPM Block Diagram (P619)

3-14

Chapter 3 Descriptions of Functions

P

VccU

VinU

Pre-driver

8V

U

V

GNDU

VccV

VinV

GNDV

VccW

VinW

W

GNDW

Vcc

VinX

GND

VinY

VinZ

B

N

VinDB

ALM

Tc overheating

protection circuit

1.5k

Fig. 3-9 IPM Block Diagram (P610, P611, P612 with Built-in Brake)

3-15

Chapter 3 Descriptions of Functions

P

VccU

VinU

Pre-driver

8V

U

V

GNDU

VccV

VinV

GNDV

VccW

VinW

W

GNDW

Vcc

VinX

GND

VinY

VinZ

N

VinDB

B

NC

Tc overheating

protection circuit

ALM

1.5k

Fig. 3-10 IPM Block Diagram (P610, P611, P612 Without Brake)

3-16

Chapter 3 Descriptions of Functions

P

VccU

VinU

ALMU

Pre-driver

1.5k

8V

U

V

GNDU

VccV

VinV

ALMV

GNDV

VccW

VinW

ALMW

1.5k

W

GNDW

Vcc

VinX

GND

VinY

VinZ

B

N

VinDB

Tc overheating

protection circuit

ALM

1.5k

Fig. 3-11 IPM Block Diagram (P621 with Built-in Brake)

3-17

Chapter 3 Descriptions of Functions

P

VccU

VinU

ALMU

Pre-driver

1.5k

8V

GNDU

VccV

U

V

VinV

ALMV

GNDV

VccW

VinW

ALMW

W

GNDW

Vcc

VinX

GND

VinY

VinZ

N

B

VinDB

NC

Tc overheating

protection circuit

ALM

1.5k

Fig. 3-12 IPM Block Diagram (P621 Without Brake)

3-18

Chapter 3 Descriptions of Functions

P

VccU

VinU

ALMU

Pre-driver

1.5k

8V

U

V

GNDU

VccV

VinV

ALMV

GNDV

VccW

VinW

ALMW

W

GNDW

Vcc

VinX

GND

VinY

VinZ

B

N

VinDB

ALM

1.5k

Fig. 3-13 IPM Block Diagram (P622 with Built-in Brake)

3-19

Chapter 3 Descriptions of Functions

P

VccU

VinU

ALMU

Pre-driver

1.5k

8V

U

V

GNDU

VccV

VinV

ALMV

GNDV

VccW

VinW

ALMW

GNDW

Vcc

W

VinX

GND

VinY

VinZ

N

B

VinDB

ALM

NC

1.5k

Fig. 3-14 IPM Block Diagram (P622 Without Brake)

3-20

Chapter 3 Descriptions of Functions

5

Timing Charts

The timing charts for the protection functions are shown in Fig. 3-15 to Fig. 3-21.

Undervoltage protection (UV) (1)

V

UV + VUH

UV

V

< 5 s

µ

< 5 s

µ

VCC

Vin

IC

5

µ

s

5

µ

s

IALM

t

ALM

t

ALM

<1>

<2>

<4>

<5>

<6>

<8>

<3>

<7>

Fig. 3-15 Timing Chart UV (1)

Refer to Fig. 3-2 <3>.

<1> If Vcc is below V_UV+ V_Hwhile V_CCis ON, an alarm is output.

<2> If the period in which V_CCfalls below V_UVis shorter than 5 µs, the protection function does not work

(while Vin is OFF).

<3> An alarm is output when a period of about 5 µs elapses after V_CCfalls below V_UVif Vin is OFF, and

IGBT remains OFF.

<4> If V_CCreturns to V_UV+ V_Hafter t_ALMelapses, UV is reset after t_ALMelapses if Vin is OFF and the

alarm is also reset simultaneously.

<5> If the period in which V_CCfalls below V_UVis shorter than 5 µs, the protection function does not work

(while Vin is ON).

<6> An alarm is output when a period of about 5 µs elapses after V_CCfalls below V_UVif Vin is ON, and

a soft IGBT shutdown occurs.

<7> If V_CCreturns to V_UV+ V_Hafter t_ALMelapses, UV is reset after t_ALMelapses if Vin is OFF and the

alarm is also reset simultaneously.

<8> An alarm is output if V_CCfalls below VUV while V_CCc is OFF.

3-21

Chapter 3 Descriptions of Functions

Undervoltage protection (UV) (2)

V

UV + VUH

UV

V

CC

Vin

I

C

µ

5 s

µ

5 s

I

ALM

tALM

t

ALM

<1>

<2>

<3>

<4>

Fig. 3-16 Timing Chart UV (2)

Refer to Fig. 3-2 <3>.

<1> If Vcc is below V_UV+ V_Hwhile V_CCis ON, an alarm is output. (Until Vin changes to OFF)

<2> If Vcc returns to V_UV+ V_Hafter t_ALMelapses, UV and the alarm are reset simultaneously with the

return of V_UV+ V_Hif Vin is OFF.

<3> Even if V_CCreturns to V_UV+ V_Hafter t_ALMelapses, UV is not reset after t_ALMelapses if Vin is ON.

UV and the alarm are reset simultaneously with Vin OFF.

<4> If Vin is ON while V_CCis OFF, the alarm is output, and a soft IGBT shutdown is executed while V_CC

is below V_UV.

3-22

Chapter 3 Descriptions of Functions

Overcurrent protection (OC)

V

in

I

OC

I

C

IALM

t

doc

t

doc

< tdoc

t

ALM

t

ALM

<4>

<5>

<6>

<1>

<2>

<3>

Fig. 3-17 Timing Chart OC

Refer to Fig. 3-2 <3>.

<1> An alarm is output and a soft IGBT shutdown is executed when t_DOCelapses after Ic rises above

Ioc.

<2> OC and the alarm are reset simultaneously if Vin is OFF when t_ALMelapses.

<3> An alarm is output and a soft IGBT shutdown is executed when t_DOCelapses after Ic rises above

Ioc.

<4> If Vin is ON when t_ALMelapses, OC is not reset. OC and the alarm are reset simultaneously when

Vin is OFF.

<5> If Vin changes to OFF before t_DOCelapses after Ic rises above Ioc, the protection function is not

activated and a normal IGBT shutdown is executed.

<6> If Vin changes to OFF before t_DOCelapses after Ic rises above Ioc, the protection function is not

activated and a normal IGBT shutdown is executed.

3-23

Chapter 3 Descriptions of Functions

Short-circuit protection

V

in

I

SC

OC

I

IC

IALM

t

doc

tdoc

< tdoc

t

ALM

tALM

<1>

<2>

<3>

<5>

<6>

<4>

Fig. 3-18 Timing Chart SC

Refer to Fig. 3-2 <2>.

<1> If the load shorts after Ic has started flowing and Ic exceeds Isc, the Ic peak is suppressed

instantly. An alarm is output and a soft IGBT shutdown is executed when t_DOCelapses.

<2> OC and the alarm are reset simultaneously if Vin is OFF when t_ALMelapses.

<3> If the load shorts and Isc is exceeded simultaneously with the start of flow of Ic, the Ic peak is

instantly suppressed. An alarm is output and a soft IGBT shutdown is executed after t_DOCelapses.

<4> If Vin is ON when t_ALMelapses, OC is not reset. OC and the alarm are reset simultaneously when

Vin is OFF.

<5> If the load shorts after Ic has started flowing and Ic exceeds Isc, the Ic peak is suppressed

instantly. Then, if Vin changes to OFF before t_DOCelapses, the protection function is not activated

and a normal IGBT shutdown occurs.

<6> If the load shorts simultaneously with the start of flow of Ic and Ic exceeds Isc, the Ic peak is

suppressed instantly. Then, if Vin changes to OFF before t_DOCelapses, the protection function is

not activated and a normal IGBT shutdown is executed.

3-24

Chapter 3 Descriptions of Functions

Case temperature overheating protection (TcOH)

Vin

TcOH

TcOH to TcH

TC

IC

IALM

1 ms

tALM

1 ms

t^ALM

<3>

<4>

<2>

<3>

<1>

Fig. 3-19 Timing Chart TcOH

Refer to Fig. 3-2 <4>.

<1> An alarm is output if the case temperature Tc continuously exceeds T_COHfor a period of about 1

ms, and if Vin is ON, a soft shutdown of all IGBTs on the lower arm side is executed.

<2> If Tc falls below T_COH-T_CHbefore t_ALMelapses, the alarm is reset when t_ALMelapses.

<3> If Tc exceeds continuously T_COHfor a period of about 1 ms, an alarm is output. (While Vin is OFF)

<4> If Tc has not fallen below T_COH-T_CHwhen t_ALMelapses, the alarm is not reset. When Tc falls below

T_COH-T_CHafter t_ALMelapses, the alarm is reset.

3-25

Chapter 3 Descriptions of Functions

IGBT chip overheating protection (TjOH) (1)

V

in

TjOH

TjOH to TjH

Tj

IC

IALM

1 ms

tALM

1 ms

t

ALM

1 ms

t

ALM

<1>

<3>

<4>

<2>

Fig. 3-20 Timing chart TjOH (1)

Refer to Fig. 3-2 <4>.

<1> An alarm is output and a soft IGBT shutdown is executed if the IGBT chip temperature Tj

continuously exceeds T_jOHfor a period of about 1 ms.

<2> If Tj falls below Tj_OH-Tj_Hbefore t_ALMelapses, OH and the alarm are simultaneously reset if Vin is

OFF when t_ALMelapses.

<3> An alarm is output if Tj continuously exceeds Tj_OHfor a period of about 1 ms, and if Vin is OFF, the

protection function is not activated.

<4> When Tj falls below Tj_OH-Tj_Hafter t_ALMelapses, OH and the alarm are reset simultaneously if Vin is

OFF.

3-26

Chapter 3 Descriptions of Functions

IGBT chip overheating protection (TjOH) (2)

Vin

TjOH

TjOH to TjH

Tj

3

s <

µ

I

C

I

ALM

< 1 ms

1 ms

tALM

< 1 ms

1 ms

tALM

<1>

<3>

<2>

Fig. 3-21 Timing Chart TjOH (2)

Refer to Fig. 3-2.

<1> If Tj exceeds Tj_OHand then falls below Tj_OHwithin about 1 ms, OH does not operate regardless of

whether Vin is ON or OFF.

<2> If Tj exceeds Tj_OHand then falls below Tj_OHwithin about 1 ms, OH does not operate regardless of

whether Vin is ON or OFF.

<3> If Tj exceeds Tj_OHand then falls below Tj_OHfor a period of about 3 µs or longer, the 1 ms detection

timer is reset.

3-27

Quality is our message

Chapter 4

Examples of Application Circuits

Contents

Page

1. Examples of Application Circuits.......................................................................4-2

2. Precautions ......................................................................................................4-7

3. Photocoupler and Peripheral Circuits ..............................................................4-10

4. Connectors......................................................................................................4-11

4–1

Chapter 4 Examples of Application Circuit

1

Examples of Application Circuits

Fig. 4-1 shows an example of an application circuit for P610, P611, and P612 (types with built-in brake).

P

20 kΩ

0.1 µF

10 µF

IF

Vcc

U

V

+

M

W

B

N

0.1 µF

20 kΩ

10 µF

IF

Vcc

5 V

10 nF

Fig. 4-1 Example of Application Circuit for P610, P611, and P612 (Types with Built-in Brake)

4-2

Chapter 4 Examples of Application Circuit

Fig. 4-2 shows an example of an application circuit for P610, P611, and P612 (types without brake).

20 kΩ

0.1 µF

P

10 µF

IF

Vcc

U

V

+

M

W

B

N

Connect to P or N.

0.1 µF

20 kΩ

10 µF

IF

Vcc

Connect to Vcc or GND

5 V

10 nF

Fig. 4-2 Example of Application Circuit for P610, P611, and P612 (Types Without Brake)

4-3

Chapter 4 Examples of Application Circuit

Fig. 4-3 shows an example of an application circuit for P621 and P622 (types with built-in brake).

P

20 kΩ

0.1 µF

10 µF

IF

Vcc

U

V

5 V

10 nF

+

IF

Vcc

W

5 V

10 nF

B

N

IF

Vcc

5 V

10 nF

0.1 µF

20 kΩ

10 µF

IF

Vcc

IF

0.1 µF

20 kΩ

5 V

10 nF

Fig. 4-3 Example of Application Circuit for P621, P622 (with Upper Arm Alarm)

(Types with Built-in Brake)

4-4

Chapter 4 Examples of Application Circuit

Fig. 4-4 shows an example of an application circuit for P621 and P622 (types without brake).

20 kΩ

0.1 µF

P

10 µF

IF

Vcc

U

V

5 V

10 nF

0.1 µF

+

10 µF

IF

Vcc

W

5 V

0.1 µF

B

N

P621: Connect to P or N

P622: Connect to N

10 µF

IF

Vcc

5 V

10 nF

0.1 µF

20 kΩ

10 µF

IF

Vcc

Connect to Vcc or GND

5 V

10 nF

Fig. 4-4 Example of Application Circuit for P621, P622 (with Upper Arm Alarm) (Types Without Brake)

4-5

Chapter 4 Examples of Application Circuit

Fig. 4-5 shows an example of an application circuit for P617.

P

20 kΩ

0.1 µF

10 µF

IF

Vcc

U

V

+

M

W

1

0.1 µF

20 kΩ

N2

10 µF

IF

Vcc

5 V

1.5 kΩ

10 nF

Fig. 4-5 Example of Application Circuit for Small-capacity IPM P617

4-6

Chapter 4 Examples of Application Circuit

Fig. 4-6 shows an example of an application circuit for P619.

P

20 kΩ

0.1 µF

10 µF

IF

Vcc

U

V

10 µF

+

M

W

10 µF

1

0.1 µF

20 kΩ

N2

10 µF

IF

Vcc

IF

5 V

10 nF

Fig. 4-6 Example of Application Circuit for Small-capacity IPM P619

2

Precautions

2.1 Control power source

As shown in the application circuit examples, a total of four isolation power sources are required for the

control power sources, 3 on the upper arm side and 1 on the lower arm side.

If you are using commercial power source units, do not connect the GND terminal on the side of the

power source output.

When the GND on the output side is connected to + or -, faulty operation occurs because each power

source is connected to the ground on the side of power source input. Stray capacity between each power

source and ground should be reduced to a minimum.

4-7

Chapter 4 Examples of Application Circuit

2.2 Structural isolation among four power sources (input connectors and PC boards)

Isolation is needed between each of the four power sources and the main power source.

Since a large amount of dv/dt is applied to this isolation during IGBT switching, keep sufficient

clearance between the components and the isolation. (2 mm or more is recommended.)

2.3 GND connection

The control power source GND on the lower arm side and the main power source GND are connected

inside the IPM. Never connect them outside the IPM. If you connect them outside the IPM, loop currents

generated inside and outside the IPM flow to the lower arm due to di/dt and cause malfunctioning of the

photocoupler and the IPM. The input circuit of the IPM may also be damaged.

2.4 Control power source capacitor

The 10 µF and 0.1 µF capacitors connected to each control power source as shown in the application

circuit examples are not intended for smoothing the control power sources, but for compensating the

wiring impedance up to the IPM. Capacitors for smoothing are needed separately.

Since transient variations may be caused in the wiring impedance from the capacitor to the control

circuit, connect the capacitor as close to the IPM control terminal and photocoupler pin as possible.

Select capacitors with lower impedance and better frequency characteristics for the electrolytic

capacitors. In addition, connect capacitors with better frequency characteristics, such as film capacitors, in

parallel.

2.5 Alarm circuits

• The potential on the secondary side of the alarm photocoupler may vary due to dv/dt. It is

recommended to stabilize the potential by connecting a capacitor of approximately 10 nF.

• As P617 does not have a built-in alarm resistor, a resistor of 1.5 kΩ must be connected on the outside

of the IPM.

2.6 Pull-up of the signal input terminal

Pull up the control signal input terminal to Vcc with a resistor of 20 kΩ. Even if you do not use the brake

in the built-in brake IPM, still pull up the DB input terminal. If you do not pull up the terminal, a malfunction

may be caused by dv/dt.

2.7 Snubber

Connect the snubber to the PN terminals directly. For the P612 package set up the snubber for each

PN terminal on both sides.

2.8 B terminal

In the case of the 6 in 1 package (without brake) type, connecting the B terminal to the N or P terminal

as described below is recommended.

P610, P611, P612, P621 ············N or P terminal

P622(Econo-IPM) ························N terminal (connection to the P terminal causes an internal short-circuit)

4-8

Chapter 4 Examples of Application Circuit

2.9 Upper arm alarm

When the upper arm alarm of an IPM with upper arm alarm output is not used, connect the alarm

terminal to Vcc to stabilize the potential.

2.10 Overcurrent protection for small-capacity IPMs

The limit level for overcurrent protection can be adjusted to a high level by adding a resistor between

the N1 and N2 terminals of small-capacity IPMs (P617, 619). The resistor added at that time must be

mounted close to the N1 and N2 terminals. A long distance from the N1 and N2 terminals can cause faulty

operation of the IPM.

2.11 IPM input circuit

The constant-current circuit shown in Fig. 4-7 is provided in the input section of our IPMs, and outflow

from the IPM takes place at the timing shown in the figure. For this reason, the IF on the primary side of

the photocoupler must be determined so that a current of IR + 1 mA flows through the pull-up resistor on

the secondary side of the photocoupler. If the IF is not sufficient, faulty operation on the secondary side is

possible.

Also, the pull-up resistor must be selected so that a current of IR + 1 mA flows on the secondary side of

the photocoupler when the photocoupler is ON and that the current flowing into the IPM at the time of OFF

does not exceed the Iin MAX listed in the specifications.

IPM

Vcc

Constant-current circuit

Pull-up resistor R

Photocoupler

SW1

I

R

1 mA

Vin

Constant-current circuit

SW2

Vcc = 15V

Zener diode −8 V

GND

1 mA flows.

IPM

Vin

SW1 ON

SW2 OFF

SW1 OFF

SW2 ON

SW1 ON

SW2 OFF

Fig. 4-7 IPM Input Circuit and Rated Current Operation Timing

4-9

Chapter 4 Examples of Application Circuit

3

Photocoupler and Peripheral Circuits

3.1 Photocoupler for control input

z Photocoupler rating

Use a photocoupler satisfying the following characteristics.

• CMH = CML > 15 kV/µs or 10 kV/µs

• tpHL = tpLH < 0.8 µs

• tpLH-tpHL = −0.4 to 0.9 µs

• CTR > 15%

Example: Product of Agilent: HCPL-4504

Product of Toshiba: TLP759 (IGM)

Note: Safety standards such as UL and VDE should also be applied.

z Wiring between photocoupler and IPM

Make the wiring between the photocoupler and the IPM as short as possible to reduce the wiring

impedance between the photocoupler and the IPM control terminal. Separate each wire between the

primary and secondary circuits so that floating capacitance does not become large, since a strong dv/dt is

applied between the primary and secondary circuits.

z Light emitting diode driving circuit

The dv/dt withstand capability of the photocoupler is also affected by the input light emitting diode driving

circuit. A driving circuit example is shown in Fig. 4-8.

Bad example: Open collector

Good example: Totempole output IC

Current limiting resistor on the cathode side of the photo diode

Bad example: Current limiting resistor on the anode side of the photo diode

Good example: Photo diode A-K is shorted by transistors C-E

(example which is particularly fit for photocoupler OFF)

Fig. 4-8 Photocoupler Input Circuits

4-10

Chapter 4 Examples of Application Circuit

3.2 Photocoupler for alarm output

z Photocoupler rating

General-purpose photocouplers can be used, but photocouplers satisfying the following characteristics are

recommended.

• 100%< CTR< 300%

• Single-element type

Example: TLP521-1-GR rank

Note: Safety standards such as UL and VDE should also be applied.

z Input current limiting resistor

A current limiting resistor for the light emitting diode in the photocoupler input is included in the IPM.

R_ALM= 1.5 kΩ and if connected directly to Vcc, about 10 mA of I_Fflows with Vcc = 15 V.

Therefore, there is no need to connect any current limiting resistor.

However, if a large amount of current, i.e., Iout > 10 mA, is needed on the photocoupler output, increase

the CTR value of the photocoupler to the required value.

z Wiring between the photocoupler and the IPM

Since a large amount of dv/dt is also applied on the photocoupler for the alarm, the same precautions as

described in 3.1 should be taken.

4

Connectors

Connectors suitable for the shape of the R-IPM control terminals are commercially available.

16-pin connector for P610, 611, 612: MDF7-25S-2.54DSA made by Hirose Electric

For P621: DF10-31S-2DSA made by Hirose Electric

Please confirm the reliability and the specifications of the above connectors with the manufacturer.

4-11

Quality is our message

Chapter 5

Cooling Design

Contents

Page

1. Cooler (Heat Sink) Selection Method ...............................................................5-2

2. Notes on Heat Sink Selection...........................................................................5-2

5–1

Chapter 5 Cooling Design

1

Cooler (Heat Sink) Selection Method

• To safeguard operation of the IGBT, make sure the junction temperature Tj does not exceed Tjmax.

Cooling should be designed in such a way that ensures that Tj is always below Tjmax even in abnormal

states such as overload operation as well as under the rated load.

• Operation of IGBT at temperatures higher than Tjmax could result in damage to the chips.

In the IPM, the TjOH protection function operates when the chip temperature of IGBT exceeds Tjmax.

However, if the temperature rises too quickly, the chip may not be protected.

• Likewise, note that the chip temperature of FWD should not exceed Tjmax.

• When selecting the cooler (heat sink), always measure the temperature directly under the center of the

chip. The Econo IPM series in particular is designed with operational preconditions for servo

applications, etc., in which the temperature increases/decreases in a short time, so care is required in

regard to heat accumulation when using under other conditions. As the structure and design place

special importance upon compactness, there is a tendency for heat to accumulate in the power chip

located at the center. For the chip layout, refer to the IPM internal structure drawing: MT6M5313. For

the concrete design, refer to the following document.

“IGBT MODULE APPLICATION MANUAL REH984”

Contents: • Power dissipation loss calculation

• Selecting heat sinks

• Heat sink mounting precautions

• Troubleshooting

2

Notes on Heat Sink Selection

How to select heat sinks is described in the manual REH982. Note also the following points.

• Flatness of the heat sink surface

Flatness between mounting screw pitches: 0 to +100 µm, roughness: 10 µm or less

If the heat sink surface is concave, a gap occurs between the heat sink and the IPM, leading to

deterioration of cooling efficiency.

If the flatness is +100 µm or more, the copper base of the IPM is deformed and cracks could occur in

the internal isolating substrates.

5-2

Quality is our message

Chapter 6

Cautions on Use

Contents

Page

1. Main Power Source ..........................................................................................6-2

2. Control Power Source ......................................................................................6-3

3. Protection Functions.........................................................................................6-4

4. Power Cycling Capability..................................................................................6-6

5. Other ................................................................................................................6-6

6–1

Chapter 6 Precautions for Use

1

Main Power Source

1.1 Voltage range

1.1.1 600 V system IPMs

• The main power source should not exceed 500 V (= V_DC(surge)) between the P and N main terminals.

The voltage between the collector and emitter main terminals (= VCES) should not exceed 600 V (=

absolute max. rated voltage).

• Surge voltage occurs in the wiring inductance inside the IPM due to di/dt during switching, but the

product is designed so that 600 V is not exceeded between the collector and emitter main terminals

when the main power source is used at V_DC(surge) or lower between the P and N main terminals.

• In order for the maximum surge voltage at the time of switching not to exceed the rated voltage, keep

the connecting wires between the IPM and the embedded product short and install a snubber close to

the P and N terminals.

1.1.2 1200 V system IPMs

• The main power source should not exceed 1000 V (= V_DC(surge)) between the P and N main terminals.

The voltage between the collector and emitter main terminals (= VCES) should not exceed 1200 V (=

absolute max. rated voltage).

• Surge voltage occurs in the wiring inductance inside the IPM due to di/dt during switching, but the

product is designed so that 1200 V is not exceeded close to the chip when the main power source is

used at V_DC(surge) or lower between the P and N main terminals.

• In order for the maximum surge voltage at the time of switching not to exceed the rated voltage, keep

the connecting wires between the IPM and the embedded product short and install a snubber close to

the P and N terminals.

1.2 External noise

Countermeasures have been taken against external noise within the IPM, but faulty operation may

possibly occur depending on the type and intensity of the noise.

Please take sufficient countermeasures against noise entering the IPM.

1.2.1 Noise from outside the equipment

• Apply a noise filter on the AC line, isolate the ground and so on.

• When required, add capacitors of 100 pF or less between all phase signal inputs and signal GND.

• Install arresters against lightning surges, etc.

6-2

Chapter 6 Precautions for Use

1.2.2 Noise from within the equipment

• Outside the rectifier: Implement the same countermeasures as the above.

• Inside the rectifier: Apply snubber circuits on the PN lines.

(In case of multiple inverters connected to one rectifier converter, etc.)

1.2.3 Noise from the output terminals

• Take external countermeasures so that contactor switching surges and so on do not enter.

2

Control Power Source

2.1 Voltage range

• The drive circuit shows stable operation when the control power source voltage is in the range of 13.5 to

16.5 V.

Operation with a value as close to 15 V as possible is recommended.

• When the control power source voltage is below 13.5 V, the loss will increase and noise will show a

tendency to decrease.

Also, the protection performance will shift, so that the protection functions may not be sufficient and chip

damage may occur.

• When the control power source voltage drops below 13.5 V, dropping down to VUV or lower, the

undervoltage protection function (UV) operates.

When the control power source voltage recovers to VUV + VH, UV is automatically released.

• When the control power source voltage exceeds 16.5 V, the loss decreases and noise shows a

tendency to increase.

Also, the protection performance will shift, so that the protection functions may not be sufficient and chip

damage may occur.

• When the control power source voltage is below 0 V (reverse bias) or exceeds 20 V, the drive circuit

and/or the main chip may be damaged. Never apply these voltages.

2.2 Voltage ripple

• The recommended voltage range of 13.5 to 16.5 V includes the voltage ripple of Vcc.

During the manufacture of the control power source, be sure to keep the voltage ripple sufficiently low.

Also be sure to keep noise superimposed on the power source sufficiently low.

• Design the control power source so as to keep dv/dt at 5 V/µs or lower.

2.3 Power source start-up sequence

• Apply the main power source after confirming that Vcc is in the recommended voltage range.

If the main power source is applied before the recommended voltage is reached, the chip may be

destroyed (worst-case scenario).

6-3

Chapter 6 Precautions for Use

2.4 Alarm at the time of power source start-up and shutdown

• At the time of power source start-up, an alarm is output at the UV protection function operation level

voltage.

Recovery is made when the protection release level voltage is reached, but as the alarm will not be

released as long as an ON signal is input, appropriate measures must be taken on the drive circuit side.

• As there is also alarm output at the time of power source shutdown, similar measures are required.

2.5 Precautions upon control circuit design

• Design with sufficient margin, taking the current consumption specification (Icc) for the drive circuit into

consideration.

• Make the wiring between the input terminals of the IPM and the photocoupler as short as possible, and

use a pattern layout with a small stray capacitance for the primary side and the secondary side of the

photocoupler.

• Install a capacitor as close as possible between Vcc and GND in the case of a high-speed photocoupler.

• For a high-speed photocoupler, use a high CMR type in which tpHL, tpLH ≤ 0.8 µs.

• For the alarm output circuit, use a low-speed photocoupler type in which CTR ≥ 100%.

• Use four isolated power sources for the control power source Vcc. Also use a design with suppressed

voltage fluctuations.

• When a capacitor is connected between the input terminals and GND, note that the response time in

regard to an input signal on the primary side of the photocoupler becomes longer.

• Design the primary-side current of the photocoupler with sufficient margin taking the CTR of the

photocoupler being used into consideration.

3

Protection Functions

As the built-in protection functions and the presence or absence of alarm output differ according to the

package and the model, confirm the protection functions of your IPM referring to the "List of IPM built-in

functions" in chapter 3.

3.1 Protection operations in general

3.1.1 Range of protection

• The protection functions included in the IPM are designed for non-repetitive abnormal phenomena.

• Do not apply constant stress that exceeds the rating.

3.1.2 Countermeasures for alarm output

• If an alarm is output, stop the input signal into the IPM immediately to stop the equipment.

• The IPM protection functions protect against abnormal phenomena, but they cannot remove the causes

of the abnormalities. After stopping the equipment, restart it after you have removed the cause of the

abnormality.

6-4

Chapter 6 Precautions for Use

3.2 Precautions for the protection functions

3.2.1 Overcurrent

• The overcurrent protection function (OC) executes a soft shutdown of the IGBT and outputs an alarm

when the overcurrent continues in excess of the insensitive time (tdoc).

Accordingly, OC does not operate when the overcurrent is removed within the tdoc period.

• In P619, the current is detected on the N-line, so there is no OC for the upper arm.

3.2.2 Starting with load short-circuit

• The OC has an insensitive time (tdoc) of approximately 5 to 10 µs. If the input signal pulse width is

shorter than this, the OC does not operate.

• If an input signal pulse width of tdoc or less continues when starting with the load shorted, short circuits

occur continuously and the chip temperature of the IGBT rises rapidly.

In such a case, the rise of the case temperature does not follow the rise of the chip temperature and the

case temperature overheating protection function (TcOH) does not operate. Normally the chip

temperature overheating protection function (TjOH) operates and provides protection, but as TjOH also

has a delay of approximately 1 ms, depending on the state of the chip temperature rise, the protection

operation may not occur in time, possibly causing damage to the chip.

3.2.3 Ground short

• If a ground short occurs and an overcurrent flows through the lower arm of the IGBT, overcurrent

protection by OC occurs for all IPMs.

• If a ground short occurs and an overcurrent flows through the upper arm of the IGBT, the protection

operation differs according to the package and the model.

P621, P622

Overcurrent protection is provided by the OC of the upper arm. Alarm output also is provided.

P610, P611, P612

Overcurrent protection is provided by the OC of the upper arm, but there is no alarm output.

For details, refer to the related document MT6M3046 "Protection in R-IPM Earth Fault Mode".

P619, P617

As there is no OC for the upper arm, there is no overcurrent protection and no alarm output.

3.3 FWD overcurrent protection

• FWD current is not detected. Accordingly, there is no protection when overcurrent flows only for FWD.

3.4 Case temperature protection

• TcOH is the protection function used when the temperature of the entire insulation substrate rises.

Accordingly, the chip temperature protection function (TjOH) operates when the heating is concentrated

on one chip.

6-5

Chapter 6 Precautions for Use

3.5 Chip temperature protection

• A chip temperature protection function (TjOH) is built into all IGBTs, including the brake part.

4

Power Cycling Capability

The lifetime of semiconductor products is not eternal. Accumulated fatigue by thermal stress resulting

from rising and falling temperatures generated within the device may shorten the lifetime of the

components. Narrow the range of temperature variations as much as possible.

5

Other

5.1 Precautions for usage and installation into equipment

(1) Also read the IPM delivery specifications for IPM use and installation into the device.

(2) Always prevent secondary damage by installing a fuse or a circuit breaker with a suitable capacity

between the commercial power source and this product, keeping in mind the possibility of chip

damage caused by unexpected accidents.

(3) When investigating the chip duty at the time of a normal turn-off operation, make sure that the

operation track for the turn-off voltage and current is within the RBSOA specifications.

When investigating the chip duty with non-repetitive short-circuit interruption, make sure that it is

within the SCSOA specifications.

(4) Use this product upon full understanding of the product usage environment and upon investigation of

whether the product reliability life is satisfactory or not. In case of use in excess of the reliability life of

the product, the chip may be destroyed before the target life of the device.

(5) Apply a thermal compound or the like between the IPM and the heat sink to make the contact heat

resistance as small as possible.

(6) Use the IPM within the range specified in the specifications for the screw torque and the heat sink

flatness.

Incorrect handling can cause insulation failure.

(7) Take care so that no load is placed on the IPM. Particularly, the control terminal should not be bent.

(8) Do not perform soldering by reflow on the main terminal and control terminal. Take care to prevent

any effect on the IPM by heat, flux, and washing solutions used for soldering other components.

(9) Avoid locations where corrosive gases are generated or dust is present.

(10) Take care to prevent high-voltage static electricity entering the main terminal and control terminal.

(11) When removing and attaching the control circuit and the IPM, first confirm that Vcc is 0 V.

6-6

Quality is our message

Chapter 7

Trouble Shooting

Contents

Page

1. Troubleshooting................................................................................................7-2

2. Fault Analysis Diagrams...................................................................................7-2

3. Alarm Cause Analysis Diagram ........................................................................7-8

7–1

Chapter 7 Troubleshooting

1

Trouble Shooting

In comparison to standard modules, IPMs have various protection functions (overcurrent, overheating,

etc.) built in, so that their devices are not easily destroyed by abnormal conditions. However, destruction

may occur depending on the abnormality, so that countermeasures are required once the cause and state

of occurrence have been clarified. An analysis diagram indicating the cause of destruction is shown on

page 2 and should be used to investigate the causes of destruction.

(For element fault judgment, refer to the Module Application Manual, chapter 4, item 2 "Fault Judgment

Method".)

Also, in the case of alarm output from the IPM, use the alarm cause analysis diagrams of Fig. 7-2 to

investigate the cause.

2

Fault Analysis Diagrams

Destruction of

IGBT part

RBSOA

IPM destruction

A

B

C

D

E

F

deviation

Gate

overvoltage

Excessive junction

temperature rise

Destruction of

FWD part

Destruction of

control circuits

Reliability

degradation

Fig. 7-1 (a.) IPM Fault Analysis Diagram (The letters A to F connect to the following diagrams.)

7-2

Chapter 7 Troubleshooting

A RBSOA deviation

[Estimated trouble location]

Excessive

shutdown current

ꢀUpper and lower

arm short-circuit

Faulty operation of

Control PCB fault

input signal circuit

ꢀExcessive turn-off current

Insufficient dead time

Control PCB fault

Abnormal load

Output short-circuit

Earth fault

Excessive power source

voltage

Abnormal input

voltage

Overvoltage

ꢀMotor regenerative

Regenerative circuit

fault

operation

No overvoltage protection

operation

Control PCB fault

ꢀInsufficient snubber

Snubber resistor wire

break

Snubber circuit fault

discharge

Off operation at the

time of short-circuit

Gate drive circuit fault

Control PCB fault

Excessive surge voltage (FWD)

at the time of reverse recovery

D

Fig. 7-1 (b) Mode A: RBSOA Deviation

B Gate overvoltage

[Estimated trouble location]

Control power

source overvoltage

Excessive power source

voltage

Control power source circuit

fault

Spike voltage

Power source wiring fault

Capacitor fault

Fig. 7-1 (c) Mode B: Gate Overvoltage

7-3

Chapter 7 Troubleshooting

C

Excessive junction temperature rise (rapid temperature rise)

[Estimated trouble location]

Steady loss

increase

Increase of saturation

voltage VCE(sat)

Insufficient control power

source voltage

Gate drive circuit fault

Control power source

circuit fault

Collector current

increase

Input signal circuit

Control PCB fault

erroneous operation

Upper and lower arm short-circuit

(repeated short-circuit)

Overcurrent

Insufficient dead time

Control PCB fault

Abnormal load

Output short-circuit

(repeated short-circuit)

Ground short

(repeated ground short)

Abnormal load

Overload

Control PCB fault

Abnormal load

Switching loss

increase

Switching frequency

increase

Carrier frequency increase

Control PCB fault

Input signal faulty operation

Control PCB fault

Input circuit fault

(oscillation)

Insufficient power

source voltage

Turn-on loss increase

Turn-off loss increase

Turn-on time increase

Excessive

turn-on current

Upper and lower arm

short-circuit

Insufficient dead time

Control PCB fault

Snubber circuit fault

Control PCB fault

Large surge voltage

Excessive

turn-off current

Upper and lower arm

short-circuit

Input signal circuit

erroneous operation

Insufficient dead time

Contact heat resistance

increase

Insufficient element

tightening

Insufficient tightening

torque

Large fin bending

Fin bending fault

Insufficient compound

quantity

Insufficient thermal compound quantity

Heat sink clogging

Decrease of cooling

performance

Insufficient dust protection

measures

Case temperature rise

Drop of cooling fan

speed or stop of fan

Defective cooling fan

Abnormal rise of

ambient temperature

Local overheating of

stack

Defective cooling system

Fig. 7-1 (d) Mode C: Excessive Rise in Junction Temperature

7-4

Chapter 7 Troubleshooting

D Destruction of FWD part

[Estimated trouble location]

Excessive rise in

Steady loss increase

Overload

Power factor drop

junction temperature

Abnormal load

Control PCB fault

Switching frequency

increase

Switching loss increase

Input signal

abnormal operation

Control PCB fault

Input signal circuit fault

Control PCB fault

Carrier frequency

increase

Contact thermal resistance

increase

Insufficient element

tightening force

Insufficient tightening torque

Fin bending fault

Large fin bending

Insufficient thermal

compound quantity

Insufficient compound quantity

Insufficient dust protection

Drop of cooling

performance

Case temperature rise

Heat sink clogging

measures

Drop of cooling fan speed

Defective cooling fan

or stop of fan

Abnormal rise of

ambient temperature

Local overheating

of stack

Defective cooling system

Excessive surge voltage at

time of reverse recovery

Overvoltage

Snubber circuit fault

di/dt increase at time

of turn-on

Control power source

voltage increase

Control power source circuit fault

Minute pulse reverse

recovery phenomenon

Gate signal breaking

by noise etc.

Control power source circuit fault

Control PCB fault

Excessive surge voltage at

time of IGBT turn-off

A

Excessive charging current to

converter part at time of use

Overcurrent

Charging circuit fault

Fig. 7-1 (e) Mode D: Destruction of FWD Part

7-5

Chapter 7 Troubleshooting

E Destruction of control circuits

[Estimated trouble location]

Excessive control power

Overvoltage

Control power source circuit fault

source voltage

Power source stabilization

Capacitor fault

Spike voltage

Long power source wiring

Control voltage application status

desorption

Excessive input part voltage

Excessive static electricity

Control circuit fault

Insufficient antistatic measures

Abnormal input pull-up resistance

Input part overcurrent

Fig. 7-1 (f) Mode E: Destruction of Control Circuit

7-6

Chapter 7 Troubleshooting

F Damage related to reliability and product handling

[Estimated trouble location]

Product loading

at time of storage

Destruction from handling

External force, load

Loading conditions

Stress at element at time of

mounting

Stress of the terminal part

Screw length

Too long screws used for main terminals

and control terminals

Excessive tightening torque

Tightening part

Terminal part

Insufficient tightening force for

main terminal screws

Excessive contact resistance

Main terminal part

Excessive vibration at time of

transport (product, equipment)

Vibration

Transport conditions

Insufficient fixing of parts at

time of product mounting

Product terminal part (check

for stress from vibration)

Dropping, impact, etc. at time

of transport

Impact shock

Transport conditions

Thermal resistance of soldered

terminals

Overheating at time of

terminal soldering

Assembly conditions at the

time of product mounting

Storage under abnormal

conditions

Storage in corrosive

atmosphere

Storage conditions

Storage in atmosphere where

condensation occurs easily

Storage in environment with

excessive dust

Reliability (life)

degradation

Storage at high temperature

(exposure to high temperatures)

Long-term storage at high

temperatures

Storage conditions

Storage at low temperatures

Long-term storage at low

temperatures

*

For the results of the

(exposure to low temperatures)

reliability tests performed

by Fuji Electric Device

Technology, refer to the

specifications and the

reliability test result report.

Excessive humidity

(exposure to humidity)

Long-term storage at high

temperature and high

Thermal stress fatigue from repeated gentle rise and fall of product temperature

Matching of application

conditions and product life

(temperature cycle, ∆Tc power cycle)

Thermal stress failure from rapid rise or fall of product temperature (thermal impact)

Thermal stress failure of wiring in product, etc., caused by change of semiconductor chip

temperature because of rapid load changes etc. (∆Tj power cycle)

Long-time voltage application under high temperature (high

temperature application (between C and E or G and E))

Long-term use at high

temperatures

Long-time voltage application at high temperature and

high humidity (application under moisture (THB))

Long-term use at high

humidity

Long-term use in atmosphere

of hydrogen sulfide, etc.

Use in a corrosive gas atmosphere

Fig. 7-1 (g) Mode F: Damage Related to Reliability and Product Handling

7-7

Chapter 7 Troubleshooting

3

Alarm Cause Analysis Diagram

3.1 Cause analysis in the event an IPM alarm occurs

When an inverter using an IPM comes to an alarm stop, a survey must first be done to find out whether

the alarm was output from the IPM or from a device control circuit (other than the IPM).

If the alarm was output by the IPM, determine the cause according to the following cause analysis

diagram.

For observation of whether there is an IPM alarm or not via the alarm output voltage, the presence or

absence of an alarm output can be confirmed easily by inserting a 1.5 kΩ resistor between the IPM alarm

terminal and the cathode of the alarm photodiode and measuring the IPM alarm terminal voltage.

Phenomenon

Explanation of alarm cause

How to determine alarm cause

IPM alarm occurrence

Normal alarm

Measure the control power source voltage Vcc,

the DC input voltage d, the output current Io.

Measure the case temperature Tc directly under

TjOH

OC

The chip temperature Tj is detected by the

temperature detection element (diode) built

into all IGBTs.

•

the chip, calculate Tj-c, and estimate Tj.

When TjOH exceeds the trip level

continuously for 1 ms or longer, the IGBT is

switched off for protection.

∆

Confirm the IPM installation method.

(Fin flatness, thermal compound, etc.)

The alarm holding time in many cases is longer

than 2 ms.

Observe the alarm and the output current (U, V,

W) with an oscilloscope.

The collector current is detected by the

current flowing through the current sensing

IGBT built into all IGBT chips.

•

Observe the alarm and the DC input current (P, N)

with an oscilloscope.

When the overcurrent trip level is exceeded

Observe the current change 5 s before alarm

continuously for approximately 5 s or longer,

µ

output.

the IGBT is switched off for protection.

Confirm the trip level and the detection location in

case of current detection with CT, etc.

The alarm holding time in many cases is 2 ms.

Observe the alarm and Vcc with an oscilloscope.

UV

When the control power source voltage Vcc

drops below the undervoltage trip level

•

Observe the power source voltage change 5

before alarm output

s

µ

continuously for 5 s or longer, the IGBT is

µ

In case of instantaneous voltage drops, the alarm

holding time in many cases is 2 ms.

switched off for protection.

•

Measure the temperature at the side of the

copper base with a thermocouple.

Observe the alarm output period with an

oscilloscope.

TcOH

The insulation substrate temperature is

detected by the temperature detection

element (IC) installed on the same ceramic

substrate as the power device.

•

The possibility that the alarm is TcOH is large

when output is made for a longer period than the

2 ms of the alarm holding time.

When the TcOH trip level is exceeded

continuously for 1 ms or longer, the IGBT is

switched off for protection.

Faulty alarm

A short pulse alarm in the order of s is output.

When the control power source voltage Vcc

•

µ

•

Observe the Vcc waveform during motor

operation with an oscilloscope, preferably in the

vicinity of the IPM control terminals.

exceeds the absolute max. rating of 20 V or

when an excessive dv/dt or ripple is

applied, the drive IC may be damaged or a

faulty alarm output.

Vcc < 20 V, dv/dt 5 V/ s, and Vripple 2 Vp-p

•

≤

µ

≤

shall apply (all four power supplies).

When noise current flows in the IPM control

•

Confirm that there is no external wiring between

IPM control GND and main terminal GND. In case

of wiring, noise current flows into the IPM control

circuit.

circuit, the IC voltage may become unstable

and a faulty alarm output.

When the drive IC is damaged, there is a high

possibility of abnormal increase of Icc.

•

Ex.: If Iccp 10 mA @Vin = "High", confirm the

≥

abnormality of IPM peripheral circuits.

Refer to "Cautions for Design and Application" and

"Application Circuit Examples" in the delivery

specifications.

Fig. 7-2 Alarm Cause Analysis Diagram

7-8


型号：	7MBP75RTJ060
厂家：	FUJI ELECTRIC
描述：	AC Motor Controller, 电动机控制
文件：	总77页 (文件大小：1921K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

7MBP75RTJ060 [FUJI]

相关型号：

7MBP75RU2A120

7MBP75TEA-060

7MBP75TEA060

7MBP75TEA120

7MBP75VDA060-50

7MBP75VDA120-50

7MBP80RTB060

7MBR100SB-060

7MBR100SB060

7MBR100SB060-01

7MBR100SB060_10

7MBR100SD060