CM150TL-24NF - Mitsubishi Electric & Electronics USA, Inc.

Feb. 2009

1

CM150TL-24NF

APPLICATION

AC drive inverters & Servo controls, etc

MITSUBISHI IGBT MODULES

CM150TL-24NF

HIGH POWER SWITCHING USE

¡IC ...................................................................150A

¡VCES ......................................................... 1200V

¡Insulated Type

¡6-elements in a pack

OUTLINE DRAWING & CIRCUIT DIAGRAM

Dimensions in mm

P

BU

N

CN-7

CN-8 CN-5

CN-6

UP-1

UP-2

V

CN-3

CN-4

VP-1

VP-2

W

CN-1

CN-2

WP-1

WP-2

NC

LABEL

U

BNP

VW

1

18

CN

11

WP VP UP

202016.5

18

110

±0.5

(6.05) (6.05)

11.7

262617.5

135

10.5

18.7

110

10.510.5

10.5 10.5

(13)

48.75

13.75

26.5

4

4-φ5.5

MOUNTING HOLES

78

±0.5

(6.05) (6.05)

2530.5 25 (13)

11

46.3

A

B

13

24.1

(SCREWING DEPTH)

6-M5 NUTS

+1

–0.5

Housing Type of A and B

(J.S.T.Mfg.Co.Ltd)

A = B8P-VH-FB-B, B = B2P-VH-FB-B

CIRCUIT DIAGRAM

Feb. 2009

2

IC = 15mA, VCE = 10V

Tj = 25°C

Tj = 125°C

VCE = 10V

VGE = 0V

VCE = VCES, VGE = 0V

±VGE = VGES, VCE = 0V

IC = 150A, VGE = 15V

VCC = 600V, IC = 150A, VGE = 15V

VCC = 600V, IC = 150A

VGE = ±15V

RG = 2.1Ω, Inductive load

IE = 150A

IE = 150A, VGE = 0V

IGBT part (1/6 module)*1

FWDi part (1/6 module)*1

Case to heat sink, Thermal compound Applied (1/6 module)

*2

1200

±20

150

300

150

300

890

–40 ~ +150

–40 ~ +125

2500

2.5 ~ 3.5

750

MITSUBISHI IGBT MODULES

CM150TL-24NF

HIGH POWER SWITCHING USE

V

A

W

°C

Vrms

N • m

g

1

0.5

3.0

—

23

2

0.45

—

130

70

400

350

150

—

3.8

0.14

0.23

—

31

mA

µA

nF

nC

ns

µC

V

K/W

Ω

—

2.1

2.4

—

675

—

5.8

—

0.051

—

2.1

7V

V

68

ns

Collector cutoff current

Gate leakage current

Input capacitance

Output capacitance

Reverse transfer capacitance

Total gate charge

Turn-on delay time

Turn-on rise time

Turn-off delay time

Turn-off fall time

Reverse recovery time

Reverse recovery charge

Emitter-collector voltage

Contact thermal resistance

External gate resistance

Gate-emitter threshold voltage

Collector-emitter saturation voltage

Thermal resistance

ICES

IGES

Cies

Coes

Cres

QG

td(on)

tr

td(off)

tf

trr (

Note 1

)

Qrr (

Note 1

)

VEC(

Note 1

)

Rth(j-c)Q

Rth(j-c)R

Rth(c-f)

RG

Symbol Parameter

VGE(th)

VCE(sat)

*1 : Case temperature (Tc) measured point is just under the chips.

If you use this value, Rth(f-a) should be measured just under the chips.

*2 : Typical value is measured by using thermally conductive grease of

λ

= 0.9[W/(m • K)].

Note 1. IE, VEC, trr & Qrr represent characteristics of the anti-parallel, emitter-collector free-wheel diode (FWDi).

2. Pulse width and repetition rate should be such that the device junction temperature (Tj) does not exceed Tjmax rating.

3. Junction temperature (Tj) should not increase beyond 150°C.

4. Pulse width and repetition rate should be such as to cause negligible temperature rise.

Collector-emitter voltage

Gate-emitter voltage

Maximum collector dissipation

Junction temperature

Storage temperature

Isolation voltage

Weight

G-E Short

C-E Short

DC, TC = 76°C*1

Pulse (Note 2)

TC = 25°C

Terminals to base plate, f = 60Hz, AC 1 minute

Main terminals M5 screw

Mounting M5 screw

Typical value

Symbol Parameter

Collector current

Emitter current

Torque strength

Conditions UnitRatings

VCES

VGES

IC

ICM

IE (

Note 1

)

IEM (

Note 1

)

PC (

Note 3

)

Tj

Tstg

Viso

—

Unit

Typ.

Limits

Min. Max.

ABSOLUTE MAXIMUM RATINGS (Tj = 25°C, unless otherwise specified)

ELECTRICAL CHARACTERISTICS (Tj = 25°C, unless otherwise specified)

Test conditions

Feb. 2009

3

MITSUBISHI IGBT MODULES

CM150TL-24NF

HIGH POWER SWITCHING USE

PERFORMANCE CURVES

0

10

1

10

2

3

5

7

10

3

2

3

5

7

0 100 200 30050 150 250

0

300

250

200

150

100

50

OUTPUT CHARACTERISTICS

(TYPICAL)

COLLECTOR CURRENT IC (A)

COLLECTOR-EMITTER VOLTAGE V

CE

(V)

Tj = 25°C

11

12

10

9

VGE =

20V 15

13

COLLECTOR-EMITTER SATURATION

VOLTAGE CHARACTERISTICS

(TYPICAL)

COLLECTOR-EMITTER

SATURATION VOLTAGE V

CE (sat)

(V)

COLLECTOR CURRENT I

C

(A)

VGE = 15V

Tj = 25°C

Tj = 125°C

10

8

6

4

2

02012 146810 16 18

GATE-EMITTER VOLTAGE V

GE

(V)

COLLECTOR-EMITTER SATURATION

VOLTAGE CHARACTERISTICS

(TYPICAL)

COLLECTOR-EMITTER

SATURATION VOLTAGE V

CE (sat)

(V)

Tj = 25°C

IC = 150A

IC = 300A

IC = 60A

12 435

FREE-WHEEL DIODE

FORWARD CHARACTERISTICS

(TYPICAL)

EMITTER CURRENT IE (A)

EMITTER-COLLECTOR VOLTAGE V

EC

(V)

Tj = 25°C

Tj = 125°C

10

–1

2

10

0

357 2

10

1

357 2

10

2

357

CAPACITANCE–VCE

CHARACTERISTICS

(TYPICAL)

CAPACITANCE C

ies

, C

oes

, C

res

(nF)

COLLECTOR-EMITTER VOLTAGE V

CE

(V)

Cies

Coes

Cres

VGE = 0V 10

0

10

1

2

3

5

7

10

2

3

5

7

10

3

2

3

5

7

10

–1

10

0

2

3

5

7

10

1

2

3

5

7

10

2

3

5

7

10

1

10

2

57

10

3

23 5723

HALF-BRIDGE

SWITCHING CHARACTERISTICS

(TYPICAL)

SWITCHING TIME (ns)

COLLECTOR CURRENT I

C

(A)

Conditions:

VCC = 600V

VGE = ±15V

RG = 2.1Ω

Tj = 125°C

Inductive load

td(off)

td(on)

tf

tr

0246810 0

4

3

2

1

Feb. 2009

4

MITSUBISHI IGBT MODULES

CM150TL-24NF

HIGH POWER SWITCHING USE

10

1

10

2

23 57

10

3

23 57

10

1

10

2

3

5

7

10

3

2

3

5

7

t

rr

I

rr

REVERSE RECOVERY CHARACTERISTICS

OF FREE-WHEEL DIODE

(TYPICAL)

EMITTER CURRENT I

E

(A)

REVERSE RECOVERY TIME t

rr

(ns)

REVERSE RECOVERY CURRENT l

rr

(A)

Conditions:

V

CC

= 600V

V

GE

= ±15V

R

G

= 2.1Ω

T

j

= 25°C

Inductive load 10

–3

10

2

10

1

10

–5

10

–4

10

0

7

5

3

2

10

–2

7

5

3

2

10

–1

7

5

3

2

10

–3

23 57 23 57 23 57 23 57

10

1

10

–2

10

–1

10

0

10

–3

10

–3

7

5

3

2

10

–2

7

5

3

2

10

–1

23 57 23 57

Single Pulse,

T

C

= 25°C

Under the chip

TRANSIENT THERMAL

IMPEDANCE CHARACTERISTICS

(IGBT part & FWDi part)

NORMALIZED TRANSIENT

THERMAL IMPEDANCE Z

th (j–c)

(ratio)

TIME (s)

IGBT part:

Per unit base =

R

th(j–c)

= 0.14K/W

FWDi part:

Per unit base =

Rth(j–c) = 0.23K/W

10

0

2

3

5

7

2

3

5

7

10

1

10

2

57

10

3

23 5723

RECOVERY LOSS vs. I

E

(TYPICAL)

RECOVERY LOSS (mJ/pulse)

EMITTER CURRENT I

E

(A)

Conditions:

V

CC

= 600V

V

GE

= ±15V

R

G

= 2.1Ω

T

j

= 125°C

Inductive load

C snubber at bus

Err

10

2

10

1

10

0

2

3

5

7

2

3

5

7

10

1

10

2

57

10

3

23 5723

SWITCHING LOSS vs.

COLLECTOR CURRENT

(TYPICAL)

SWITCHING LOSS (mJ/pulse)

COLLECTOR CURRENT I

C

(A)

Conditions:

V

CC

= 600V

V

GE

= ±15V

R

G

= 2.1Ω

T

j

= 125°C

Inductive load

C snubber at bus

Esw(off)

Esw(on)

SWITCHING LOSS vs.

GATE RESISTANCE

(TYPICAL)

SWITCHING LOSS (mJ/pulse)

GATE RESISTANCE R

G

(Ω)

10

2

10

1

10

0

Conditions:

V

CC

= 600V

V

GE

= ±15V

I

C

= 150A

T

j

= 125°C

Inductive load

C snubber at bus

Esw(off)

Esw(on)

2

3

5

7

2

3

5

7

10

0

10

1

57

10

2

23 5723

10

2

10

1

10

0

2

3

5

7

2

3

5

7

10

0

10

1

57

10

2

23 5723

RECOVERY LOSS vs.

GATE RESISTANCE

(TYPICAL)

RECOVERY LOSS (mJ/pulse)

GATE RESISTANCE R

G

(Ω)

Conditions:

V

CC

= 600V

V

GE

= ±15V

I

E

= 150A

T

j

= 125°C

Inductive load

C snubber at bus

Err

Feb. 2009

5

0 200 400 600 800 1000

GATE CHARGE

CHARACTERISTICS

(TYPICAL)

GATE-EMITTER VOLTAGE VGE (V)

GATE CHARGE QG (nC)

V

CC

= 600V

V

CC

= 400V

I

C

= 150A

0

4

8

16

12

20

00

MITSUBISHI IGBT MODULES

CM150TL-24NF

HIGH POWER SWITCHING USE