10-E206PMA050SA-L184A38Z

datasheet

flowPIM E2

600 V / 50 A

Features

flow E1 12 mm housing

● Trench Fieldstop IGBT3 technology

● Standard industrial housing

● Optimized Rth(j-s) with Phase Change Material

● Built-in NTC

Schematic

Target applications

● Industrial Drives

Types

● 10-E206PMA050SA-L184A38Z

Copyright Vincotech

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20 Aug. 2021 / Revision 4

10-E206PMA050SA-L184A38Z

datasheet

Maximum Ratings

T_j= 25 °C, unless otherwise specified

Parameter

Symbol

Conditions

Value

Unit

Inverter Switch

V_CES

Collector-emitter voltage

600

51

V

A

I_C

Collector current (DC current)

Repetitive peak collector current

Total power dissipation

T_j= T_jmax

T_s= 80 °C

T_j= 150 °C

I_CRM

t_plimited by T_jmax

T_j= T_jmax

150

95

A

P_tot

W

V

V_GES

Gate-emitter voltage

±20

6

t_SC

Short circuit ratings

V_GE= 15 V, V_CC= 360 V

µs

°C

T_jmax

Maximum junction temperature

175

Inverter Diode

V_RRM

Peak repetitive reverse voltage

600

46

V

A

I_F

Forward current (DC current)

Repetitive peak forward current

Total power dissipation

T_j= T_jmax

T_s= 80 °C

I_FRM

t_plimited by T_jmax

T_j= T_jmax

100

67

A

P_tot

W

°C

T_jmax

Maximum junction temperature

175

Brake Switch

V_CES

Collector-emitter voltage

600

51

V

A

I_C

Collector current (DC current)

Repetitive peak collector current

Total power dissipation

T_j= T_jmax

T_s= 80 °C

T_j= 150 °C

I_CRM

t_plimited by T_jmax

T_j= T_jmax

150

95

A

P_tot

W

V

V_GES

Gate-emitter voltage

±20

6

t_SC

Short circuit ratings

V_GE= 15 V, V_CC= 360 V

µs

°C

T_jmax

Maximum junction temperature

175

Copyright Vincotech

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20 Aug. 2021 / Revision 4

10-E206PMA050SA-L184A38Z

datasheet

Maximum Ratings

T_j= 25 °C, unless otherwise specified

Parameter

Symbol

Conditions

Value

Unit

Brake Diode

V_RRM

Peak repetitive reverse voltage

600

28

V

A

I_F

Forward current (DC current)

Repetitive peak forward current

Total power dissipation

T_j= T_jmax

T_s= 80 °C

I_FRM

t_plimited by T_jmax

T_j= T_jmax

40

A

P_tot

50

W

°C

T_jmax

Maximum junction temperature

175

Rectifier Diode

V_RRM

Peak repetitive reverse voltage

1600

58

V

A

I_F

Forward current (DC current)

Surge (non-repetitive) forward current

Surge current capability

T_j= T_jmax

T_s= 80 °C

T_j= 150 °C

T_s= 80 °C

I_FSM

I²t

400

800

68

A

Single Half Sine Wave,

t_p= 10 ms

A²s

W

°C

P_tot

Total power dissipation

T_j= T_jmax

T_jmax

Maximum junction temperature

150

Module Properties

Thermal Properties

T_stg

T_jop

Storage temperature

-40…+125

°C

Operation temperature under switching

condition

-40…+(T_jmax- 25)

Isolation Properties

Isolation voltage

Creepage distance

Clearance

V_isol

DC Test Voltage*

AC Voltage

t_p= 2 s

6000

2500

>12,7

8,83

V

t_p= 1 min

V

mm

Comparative Tracking Index

*100 % tested in production

CTI

≥ 600

Copyright Vincotech

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10-E206PMA050SA-L184A38Z

datasheet

Characteristic Values

Symbol

Parameter

Conditions

Values

Typ

Unit

V_CE[V] I_C[A]

V_DS[V] I_D[A] T_j[°C]

V_GE[V]

V_GS[V]

Min

Max

V_F[V]

I_F[A]

Inverter Switch

Static

V_GE(th)

Gate-emitter threshold voltage

V_CE= V_GE

0,0008

50

25

5

5,8

6,5

V

25

1,05

1,58

1,75

1,8

1,85⁽¹⁾

V_CEsat

Collector-emitter saturation voltage

15

125

150

I_CES

I_GES

r_g

Collector-emitter cut-off current

Gate-emitter leakage current

Internal gate resistance

Input capacitance

0

600

0

25

2,6

µA

nA

Ω

20

600

None

3140

200

93

C_ies

C_oes

C_res

pF

Output capacitance

f = 1 Mhz

0

25

Reverse transfer capacitance

Thermal

λ_paste= 3,4 W/mK

(PSX)

(2)

R_th(j-s)

Thermal resistance junction to sink

Dynamic

1

K/W

25

95

100,4

13,6

t_d(on)

Turn-on delay time

ns

150

25

t_r

Rise time

150

25

17,6

R_gon= 8 Ω

R_goff= 8 Ω

161

t_d(off)

Turn-off delay time

ns

150

25

184,2

109,05

131,26

0,675

1,02

±15

300

50

t_f

Fall time

ns

150

25

Q_rFWD=2,29 µC

Q_rFWD=4,37 µC

E_on

E_off

Turn-on energy (per pulse)

Turn-off energy (per pulse)

mWs

150

25

1,3

150

1,76

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10-E206PMA050SA-L184A38Z

datasheet

Characteristic Values

Symbol

Parameter

Conditions

Values

Typ

Unit

V_CE[V] I_C[A]

V_DS[V] I_D[A] T_j[°C]

V_GE[V]

V_GS[V]

Min

Max

V_F[V]

I_F[A]

Inverter Diode

Static

25

1,2

1,64

1,56

1,54

1,9⁽¹⁾

V_F

I_R

Forward voltage

50

125

150

V

Reverse leakage current

Thermal

V_r= 600 V

25

27

µA

λ_paste= 3,4 W/mK

(PSX)

(2)

R_th(j-s)

Thermal resistance junction to sink

Dynamic

1,41

K/W

25

51,6

62,38

129,99

171,85

2,29

I_RRM

Peak recovery current

Reverse recovery time

Recovered charge

A

150

25

t_rr

ns

150

25

di/dt=3939 A/µs

di/dt=3496 A/µs

Q_r

±15

300

50

μC

150

25

4,37

0,515

0,917

3909

E_rec

Reverse recovered energy

Peak rate of fall of recovery current

mWs

A/µs

150

25

(di_rf/dt)_max

150

2375

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10-E206PMA050SA-L184A38Z

datasheet

Characteristic Values

Symbol

Parameter

Conditions

Values

Typ

Unit

V_CE[V] I_C[A]

V_DS[V] I_D[A] T_j[°C]

V_GE[V]

V_GS[V]

Min

Max

V_F[V]

I_F[A]

Brake Switch

Static

V_GE(th)

Gate-emitter threshold voltage

V_CE= V_GE

0,0008

50

25

5

5,8

6,5

V

25

1,05

1,58

1,75

1,8

1,85⁽¹⁾

V_CEsat

Collector-emitter saturation voltage

15

125

150

I_CES

I_GES

r_g

Collector-emitter cut-off current

Gate-emitter leakage current

Internal gate resistance

Input capacitance

0

600

0

25

2,6

µA

nA

Ω

20

600

None

3140

200

93

C_ies

C_oes

C_res

pF

Output capacitance

f = 1 Mhz

0

25

Reverse transfer capacitance

Thermal

λ_paste= 3,4 W/mK

(PSX)

(2)

R_th(j-s)

Thermal resistance junction to sink

Dynamic

1

K/W

25

26

27

t_d(on)

Turn-on delay time

Rise time

125

150

25

ns

24

21

t_r

125

150

25

23

24

R_gon= 4 Ω

R_goff= 4 Ω

198

222

225

76,11

84,5

81,03

1,55

1,92

2,05

1,26

1,73

1,85

t_d(off)

Turn-off delay time

Fall time

125

150

25

ns

0/15

400

50

t_f

125

150

25

ns

Q_rFWD=1,33 µC

Q_rFWD=2,47 µC

Q_rFWD=2,75 µC

E_on

Turn-on energy (per pulse)

Turn-off energy (per pulse)

125

150

25

mWs

E_off

125

150

Copyright Vincotech

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20 Aug. 2021 / Revision 4

10-E206PMA050SA-L184A38Z

datasheet

Characteristic Values

Symbol

Parameter

Conditions

Values

Typ

Unit

V_CE[V] I_C[A]

V_DS[V] I_D[A] T_j[°C]

V_GE[V]

V_GS[V]

Min

Max

V_F[V]

I_F[A]

Brake Diode

Static

25

1,25

1,7

1,95⁽¹⁾

V_F

I_R

Forward voltage

20

125

150

1,58

V

Reverse leakage current

Thermal

V_r= 600 V

25

27

µA

λ_paste= 3,4 W/mK

(PSX)

(2)

R_th(j-s)

Thermal resistance junction to sink

Dynamic

1,91

K/W

25

13,38

16,42

16,18

223,35

318,92

347,28

1,33

I_RRM

Peak recovery current

125

150

25

A

t_rr

Reverse recovery time

125

150

25

ns

di/dt=1871 A/µs

di/dt=1589 A/µs

di/dt=1559 A/µs

Q_r

Recovered charge

0/15

400

50

125

150

25

2,47

μC

2,75

0,335

0,628

0,72

E_rec

Reverse recovered energy

Peak rate of fall of recovery current

125

150

25

mWs

A/µs

1138

(di_rf/dt)_max

125

150

33,2

30,22

Copyright Vincotech

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20 Aug. 2021 / Revision 4

10-E206PMA050SA-L184A38Z

datasheet

Characteristic Values

Symbol

Parameter

Conditions

Values

Typ

Unit

V_CE[V] I_C[A]

V_DS[V] I_D[A] T_j[°C]

V_F[V] I_F[A]

V_GE[V]

V_GS[V]

Min

Max

Rectifier Diode

Static

25

1,09

1,02

1,5⁽¹⁾

V_F

I_R

Forward voltage

35

125

150

25

V

100

Reverse leakage current

Thermal

V_r= 1600 V

µA

150

2000

λ_paste= 3,4 W/mK

(PSX)

(2)

R_th(j-s)

Thermal resistance junction to sink

1,03

K/W

Thermistor

Static

R

Δ_R/R

P

Rated resistance

Deviation of R₁₀₀

Power dissipation

Power dissipation constant

B-value

25

5

kΩ

%

R₁₀₀= 493 Ω

100

-5

5

245

1,4

mW

mW/K

K

d

25

B_(25/50)

Tol. ±2 %

3375

3437

B_(25/100)

B-value

K

Vincotech Thermistor Reference

K

(1)

Value at chip level

(2)

Only valid with pre-applied Vincotech thermal interface material.

Copyright Vincotech

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20 Aug. 2021 / Revision 4

10-E206PMA050SA-L184A38Z

datasheet

Inverter Switch Characteristics

figure 1.

IGBT

figure 2.

IGBT

Typical output characteristics

I_C= f(V_CE

)

I_C= f(V_CE)

150

V_GE

:

7 V

8 V

125

100

75

50

25

0

125

100

75

50

25

0

9 V

10 V

11 V

12 V

13 V

14 V

15 V

16 V

17 V

0,0

0,5

1,0

1,5

2,0

2,5

3,0

3,5

4,0

4,5

0,0

0,5

1,0

1,5

2,0

2,5

3,0

3,5

4,0

4,5

V

_CE(V)

V_CE(V)

t_p

=

t_p

=

250

15

μs

V

250

150

μs

°C

25 °C

V_GE

=

T_j=

125 °C

150 °C

T_j:

V_GEfrom 7 V to 17 V in steps of 1 V

figure 3.

IGBT

figure 4.

IGBT

Typical transfer characteristics

Transient thermal impedance as a function of pulse width

I_C= f(V_GE

)

Z_th(j-s)= f(t_p)

0

50

10

40

30

20

10

-1

10

-2

10

0,5

0,2

0,1

-3

10

0,05

0,02

0,01

0,005

0

-4

0

10

-5

-4

10

-3

10

-2

10

-1

10

0

10

1

10

2

4

6

8

10

t_p(s)

V

_GE(V)

t_p

V_CE

=

250

10

μs

V

D =

t_p/ T

0,995

25 °C

125 °C

150 °C

R_th(j-s)=

T_j:

K/W

IGBT thermal model values

R (K/W)

τ (s)

1,45E-01

5,28E-01

2,00E-01

8,09E-02

4,17E-02

7,02E-01

9,42E-02

2,95E-02

5,41E-03

5,79E-04

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datasheet

Inverter Switch Characteristics

figure 5.

IGBT

Safe operating area

I_C= f(V_CE

)

1000

100

10

100µs

1ms

1

10ms

100ms

DC

0,1

0,01

1

10

100

1000

10000

V

_CE(V)

D =

single pulse

T_s=

80

15

°C

V

V_GE

=

T_j=

T_jmax

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10-E206PMA050SA-L184A38Z

datasheet

Inverter Diode Characteristics

figure 6.

FWD

figure 7.

FWD

Typical forward characteristics

Transient thermal impedance as a function of pulse width

I_F= f(V_F)

Z_th(j-s)= f(t_p)

1

150

125

100

75

10

0

10

-1

10

50

0,5

0,2

0,1

-2

10

0,05

0,02

0,01

0,005

0

25

-3

0

0,0

10

-5

-4

10

-3

10

-2

10

-1

10

0

1

2

0,5

1,0

1,5

2,0

2,5

3,0

10

t_p(s)

V_F(V)

t_p

=

250

μs

D =

t_p/ T

1,414

25 °C

125 °C

150 °C

R_th(j-s)=

T_j:

K/W

FWD thermal model values

R (K/W)

τ (s)

7,38E-02

1,47E-01

6,53E-01

3,22E-01

1,24E-01

9,40E-02

2,82E+00

4,00E-01

7,18E-02

2,02E-02

4,33E-03

4,82E-04

Copyright Vincotech

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10-E206PMA050SA-L184A38Z

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Brake Switch Characteristics

figure 8.

IGBT

figure 9.

IGBT

Typical output characteristics

I_C= f(V_CE

)

I_C= f(V_CE)

150

V_GE

:

7 V

8 V

125

100

75

50

25

0

125

100

75

50

25

0

9 V

10 V

11 V

12 V

13 V

14 V

15 V

16 V

17 V

0,0

0,5

1,0

1,5

2,0

2,5

3,0

3,5

4,0

4,5

0,0

0,5

1,0

1,5

2,0

2,5

3,0

3,5

4,0

4,5

V

_CE(V)

V_CE(V)

t_p

=

t_p

=

250

15

μs

V

250

150

μs

°C

25 °C

V_GE

=

T_j=

125 °C

150 °C

T_j:

V_GEfrom 7 V to 17 V in steps of 1 V

figure 10.

IGBT

figure 11.

IGBT

Typical transfer characteristics

Transient thermal impedance as a function of pulse width

I_C= f(V_GE

)

Z_th(j-s)= f(t_p)

0

50

10

40

30

20

10

-1

10

-2

10

0,5

0,2

0,1

-3

10

0,05

0,02

0,01

0,005

0

-4

0

10

-5

-4

10

-3

10

-2

10

-1

10

0

10

1

10

2

4

6

8

10

t_p(s)

V

_GE(V)

t_p

V_CE

=

250

10

μs

V

D =

t_p/ T

0,995

25 °C

125 °C

150 °C

R_th(j-s)=

T_j:

K/W

IGBT thermal model values

R (K/W)

τ (s)

1,45E-01

5,28E-01

2,00E-01

8,09E-02

4,17E-02

7,02E-01

9,42E-02

2,95E-02

5,41E-03

5,79E-04

Copyright Vincotech

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10-E206PMA050SA-L184A38Z

datasheet

Brake Switch Characteristics

figure 12.

IGBT

Safe operating area

I_C= f(V_CE

)

1000

100

10

100µs

1ms

1

10ms

100ms

DC

0,1

0,01

1

10

100

1000

10000

V

_CE(V)

D =

single pulse

T_s=

80

15

°C

V

V_GE

=

T_j=

T_jmax

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datasheet

Brake Diode Characteristics

figure 13.

FWD

figure 14.

FWD

Typical forward characteristics

Transient thermal impedance as a function of pulse width

I_F= f(V_F)

Z_th(j-s)= f(t_p)

1

60

50

40

30

20

10

0

10

0

10

-1

10

0,5

0,2

0,1

-2

10

0,05

0,02

0,01

0,005

0

-3

10

-5

-4

10

-3

10

-2

10

-1

10

0

1

2

0,0

0,5

1,0

1,5

2,0

2,5

3,0

10

t_p(s)

V_F(V)

t_p

=

250

μs

D =

t_p/ T

1,914

25 °C

125 °C

150 °C

R_th(j-s)=

T_j:

K/W

FWD thermal model values

R (K/W)

τ (s)

8,07E-02

2,18E-01

8,50E-01

4,32E-01

2,00E-01

1,34E-01

2,21E+00

2,22E-01

4,41E-02

9,35E-03

1,60E-03

2,12E-04

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10-E206PMA050SA-L184A38Z

datasheet

Rectifier Diode Characteristics

figure 15.

Rectifier

figure 16.

Rectifier

Typical forward characteristics

Transient thermal impedance as a function of pulse width

I_F= f(V_F)

Z_th(j-s)= f(t_p)

1

100

75

50

25

0

10

0

10

-1

10

-2

10

0,5

0,2

0,1

-3

0,05

0,02

0,01

0,005

0

10

-4

10

-5

-4

10

-3

10

-2

10

-1

10

0

1

2

0,00

0,25

0,50

μs

0,75

1,00

1,25

1,50

1,75

V_F(V)

10

t_p(s)

t_p

=

250

D =

t_p/ T

1,032

25 °C

125 °C

150 °C

R_th(j-s)=

T_j:

K/W

Rectifier thermal model values

R (K/W)

τ (s)

4,86E-02

1,31E-01

5,24E-01

1,97E-01

8,14E-02

4,98E-02

5,67E+00

6,68E-01

9,95E-02

3,35E-02

4,54E-03

8,29E-04

Copyright Vincotech

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10-E206PMA050SA-L184A38Z

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Thermistor Characteristics

figure 17.

Thermistor

Typical NTC characteristic as function of temperature

R_T= f(T)

6000

5000

4000

3000

2000

1000

0

20

40

60

80

100

120

140

T(°C)

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datasheet

Inverter Switching Characteristics

figure 18.

IGBT

figure 19.

IGBT

Typical switching energy losses as a function of collector current

Typical switching energy losses as a function of gate resistor

E = f(I_C)

E = f(R_g)

3,0

2,5

2,0

1,5

1,0

0,5

0,0

3,0

2,5

2,0

1,5

1,0

0,5

0,0

E_off

E_on

E_off

E_on

E_off

E_on

0

20

40

60

80

100

I_C(A)

0

5

10

15

20

25

30

35

R_g(Ω)

With an inductive load at

25 °C

T_j:

V_CE

V_GE

=

V_CE

V_GE

I_C

=

300

±15

8

V

Ω

150 °C

300

±15

50

V

150 °C

V

A

R_gon

R_goff

8

figure 20.

FWD

figure 21.

FWD

Typical reverse recovered energy loss as a function of collector current

Typical reverse recovered energy loss as a function of gate resistor

E_rec= f(I_C)

E_rec= f(R_g)

1,50

1,25

1,00

0,75

0,50

0,25

0,00

1,25

1,00

0,75

0,50

0,25

0,00

E_rec

0

20

40

60

80

100

0

5

10

15

20

25

30

35

I_C(A)

R_g(Ω)

With an inductive load at

25 °C

T_j:

V_CE

V_GE

R_gon

=

V_CE

V_GE

I_C

=

300

±15

8

V

Ω

150 °C

300

±15

50

V

A

150 °C

Copyright Vincotech

17

20 Aug. 2021 / Revision 4

10-E206PMA050SA-L184A38Z

datasheet

Inverter Switching Characteristics

figure 22.

IGBT

figure 23.

IGBT

Typical switching times as a function of collector current

Typical switching times as a function of gate resistor

t = f(I_C)

t = f(R_g)

0

10

0

10

t_d(off)

t_d(on)

t_d(off)

t_f

t_d(on)

t_f

-1

10

-1

10

t_r

-2

10

-2

10

-3

10

-3

10

0

20

40

60

80

100

I_C(A)

0

5

10

15

20

25

30

35

R_g(Ω)

With an inductive load at

T_j=

150

300

±15

8

°C

V

150

300

±15

50

°C

V_CE

=

V_CE

=

V

A

V_GE

R_gon

R_goff

V_GE

I_C

V

Ω

8

figure 24.

FWD

figure 25.

FWD

Typical reverse recovery time as a function of collector current

Typical reverse recovery time as a function of IGBT turn off gate resistor

t_rr= f(I_C)

t_rr= f(R_goff)

0,35

0,30

0,25

0,20

0,15

0,10

0,05

0,00

0,40

0,35

0,30

0,25

0,20

0,15

0,10

0,05

0,00

t_rr

0

20

40

60

80

100

0

5

10

15

20

25

30

35

I_C(A)

R_goff(Ω)

With an inductive load at

25 °C

T_j:

V_CE

V_GE

R_gon

=

V_CE

V_GE

I_C

=

300

±15

8

V

Ω

150 °C

300

±15

50

V

A

150 °C

Copyright Vincotech

18

20 Aug. 2021 / Revision 4

10-E206PMA050SA-L184A38Z

datasheet

Inverter Switching Characteristics

figure 26.

FWD

figure 27.

FWD

Typical recovered charge as a function of collector current

Typical recovered charge as a function of turn off gate resistor

Q_r= f(I_C)

Q_r= f(R_goff)

8

7

6

5

4

3

2

1

0

6

5

4

3

2

1

0

Q_r

0

20

40

60

80

100

0

5

10

15

20

25

30

35

I_C(A)

R_goff(Ω)

With an inductive load at

25 °C

T_j:

V_CE

V_GE

R_gon

=

V_CE

V_GE

I_C

=

300

±15

8

V

Ω

150 °C

300

±15

50

V

150 °C

V

A

figure 28.

FWD

figure 29.

FWD

Typical peak reverse recovery current as a function of collector current

Typical peak reverse recovery current as a function of turn off gate resistor

I_RM= f(I_C)

I_RM= f(R_goff)

70

60

50

40

30

20

10

0

125

100

75

50

25

0

I_RM

0

20

40

60

80

100

0

5

10

15

20

25

30

35

I_C(A)

R_goff(Ω)

With an inductive load at

25 °C

T_j:

V_CE

V_GE

R_gon

=

V_CE

V_GE

I_C

=

300

±15

8

V

Ω

150 °C

300

±15

50

V

A

150 °C

Copyright Vincotech

19

20 Aug. 2021 / Revision 4

10-E206PMA050SA-L184A38Z

datasheet

Inverter Switching Characteristics

figure 30.

FWD

figure 31.

FWD

Typical rate of fall of forward and reverse recovery current as a function of collector current

Typical rate of fall of forward and reverse recovery current as a function of turn off gate resistor

di_F/dt, di_rr/dt = f(I_C)

di_F/dt, di_rr/dt = f(R_goff)

6000

12000

10000

8000

6000

4000

2000

0

di_F/dt ‒ ‒ ‒ ‒ ‒

di_rr/dt ──────

5000

4000

3000

2000

1000

0

20

40

60

80

100

I_C(A)

0

5

10

15

20

25

30

35

R

_goff(Ω)

With an inductive load at

25 °C

T_j:

V_CE

V_GE

R_gon

=

V_CE

V_GE

I_C

=

300

±15

8

V

Ω

150 °C

300

±15

50

V

A

150 °C

figure 32.

IGBT

Reverse bias safe operating area

I_C= f(V_CE

)

120

I_{C MAX}

100

80

60

40

20

0

100

200

300

400

500

600

700

V

_CE(V)

T_j=

At

150

8

°C

R_gon

R_goff

=

Ω

8

Copyright Vincotech

20

20 Aug. 2021 / Revision 4

10-E206PMA050SA-L184A38Z

datasheet

Brake Switching Characteristics

figure 33.

IGBT

figure 34.

IGBT

Typical switching energy losses as a function of collector current

Typical switching energy losses as a function of gate resistor

E = f(I_C)

E = f(R_g)

6

5

4

3

2

1

0

6

5

4

3

2

1

0

E_on

E_off

0

20

40

60

80

100

I_C(A)

0

5

10

15

20

25

30

35

R_g(Ω)

With an inductive load at

25 °C

V_CE

V_GE

=

V_CE

V_GE

I_C

=

400

0/15

4

V

Ω

125 °C

150 °C

400

0/15

50

V

125 °C

150 °C

T_j:

V

A

R_gon

R_goff

4

figure 35.

FWD

figure 36.

FWD

Typical reverse recovered energy loss as a function of collector current

Typical reverse recovered energy loss as a function of gate resistor

E_rec= f(I_C)

E_rec= f(R_g)

1,0

0,8

0,6

0,4

0,2

0,0

0,9

0,8

0,7

0,6

0,5

0,4

0,3

0,2

0,1

0,0

E_rec

0

20

40

60

80

100

I_C(A)

0

5

10

15

20

25

30

35

R_g(Ω)

With an inductive load at

25 °C

V_CE

V_GE

R_gon

=

V_CE

V_GE

I_C

=

400

0/15

4

V

Ω

125 °C

150 °C

400

0/15

50

V

125 °C

150 °C

T_j:

V

A

Copyright Vincotech

21

20 Aug. 2021 / Revision 4

10-E206PMA050SA-L184A38Z

datasheet

Brake Switching Characteristics

figure 37.

IGBT

figure 38.

IGBT

Typical switching times as a function of collector current

Typical switching times as a function of gate resistor

t = f(I_C)

t = f(R_g)

0

10

0

10

t_d(off)

-1

10

t_f

t_r

t_d(on)

-1

10

t_r

t_d(on)

-2

10

t_f

-3

10

-2

10

0

20

40

60

80

100

0

5

10

15

20

25

30

35

R_g(Ω)

I_C(A)

With an inductive load at

T_j=

150

400

0/15

4

°C

V

150

400

0/15

50

°C

V_CE

=

V_CE

=

V

A

V_GE

R_gon

R_goff

V_GE

I_C

V

Ω

4

figure 39.

FWD

figure 40.

FWD

Typical reverse recovery time as a function of collector current

Typical reverse recovery time as a function of IGBT turn off gate resistor

t_rr= f(I_C)

t_rr= f(R_goff)

0,6

0,5

0,4

0,3

0,2

0,1

0,0

0,6

0,5

0,4

0,3

0,2

0,1

0,0

t_rr

0

20

40

60

80

100

0

5

10

15

20

25

30

35

I_C(A)

R_goff(Ω)

With an inductive load at

25 °C

V_CE

V_GE

R_gon

=

V_CE

V_GE

I_C

=

400

0/15

4

V

Ω

125 °C

150 °C

400

0/15

50

V

125 °C

150 °C

T_j:

V

A

Copyright Vincotech

22

20 Aug. 2021 / Revision 4

10-E206PMA050SA-L184A38Z

datasheet

Brake Switching Characteristics

figure 41.

FWD

figure 42.

FWD

Typical recovered charge as a function of collector current

Typical recovered charge as a function of turn off gate resistor

Q_r= f(I_C)

Q_r= f(R_goff)

4,5

4,0

3,5

3,0

2,5

2,0

1,5

1,0

0,5

0,0

3,5

3,0

2,5

2,0

1,5

1,0

0,5

0,0

Q_r

0

20

40

60

80

100

0

5

10

15

20

25

30

35

I_C(A)

R_goff(Ω)

With an inductive load at

25 °C

V_CE

V_GE

R_gon

=

V_CE

V_GE

I_C

=

400

0/15

4

V

Ω

125 °C

150 °C

400

0/15

50

V

125 °C

150 °C

T_j:

V

A

figure 43.

FWD

figure 44.

FWD

Typical peak reverse recovery current as a function of collector current

Typical peak reverse recovery current as a function of turn off gate resistor

I_RM= f(I_C)

I_RM= f(R_goff)

20,0

17,5

15,0

12,5

10,0

7,5

22,5

20,0

17,5

15,0

12,5

10,0

7,5

I_RM

5,0

2,5

0,0

0

20

40

60

80

100

0

5

10

15

20

25

30

35

I_C(A)

R_goff(Ω)

With an inductive load at

25 °C

V_CE

V_GE

R_gon

=

V_CE

V_GE

I_C

=

400

0/15

4

V

Ω

125 °C

150 °C

400

0/15

50

V

A

125 °C

150 °C

T_j:

Copyright Vincotech

23

20 Aug. 2021 / Revision 4

10-E206PMA050SA-L184A38Z

datasheet

Brake Switching Characteristics

figure 45.

FWD

figure 46.

FWD

Typical rate of fall of forward and reverse recovery current as a function of collector current

Typical rate of fall of forward and reverse recovery current as a function of turn off gate resistor

di_F/dt, di_rr/dt = f(I_C)

di_F/dt, di_rr/dt = f(R_goff)

3000

2500

2000

1500

1000

500

di_F/dt ‒ ‒ ‒ ‒ ‒

di_rr/dt ──────

2500

2000

1500

1000

500

0

20

40

60

80

100

I_C(A)

0

5

10

15

20

25

30

35

R

_goff(Ω)

With an inductive load at

25 °C

V_CE

V_GE

R_gon

=

V_CE

V_GE

I_C

=

400

0/15

4

V

Ω

125 °C

150 °C

400

0/15

50

V

A

125 °C

150 °C

T_j:

figure 47.

IGBT

Reverse bias safe operating area

I_C= f(V_CE

)

120

I_{C MAX}

100

80

60

40

20

0

100

200

300

400

500

600

700

V

_CE(V)

T_j=

At

150

4

°C

R_gon

R_goff

=

Ω

4

Copyright Vincotech

24

20 Aug. 2021 / Revision 4

10-E206PMA050SA-L184A38Z

datasheet

Switching Definitions

figure 48.

IGBT

figure 49.

IGBT

Turn-off Switching Waveforms & definition of t_doff, t_Eoff(t_tEoff= integrating time for E_off

)

Turn-on Switching Waveforms & definition of t_don, t_Eon(t_Eon= integrating time for E_on)

t_doff

%

V_{GE 90%}

V_{CE 90%}

I_C

V_GE

V_CE

t_don

t_Eoff

I_{C 1%}

V_{CE 3%}

V_CE

I_{C 10%}

V_{GE 10%}

t_Eon

t (µs)

figure 50.

IGBT

figure 51.

IGBT

Turn-off Switching Waveforms & definition of t_f

Turn-on Switching Waveforms & definition of t_r

fitted

%

I_C

%

I_{C 90%}

I_C

I_{C 60%}

V_CE

I_{C 40%}

I_{C 90%}

t_r

I_C10%

V_CE

C 10%

t_f

t (µs)

Copyright Vincotech

25

20 Aug. 2021 / Revision 4

10-E206PMA050SA-L184A38Z

datasheet

Switching Definitions

figure 52.

FWD

figure 53.

FWD

Turn-off Switching Waveforms & definition of t_rr

Turn-on Switching Waveforms & definition of t_Qr(t_Qr= integrating time for Q_r)

%

Q_r

%

t_Qr

t_rr

I_F

fitted

RRM 10%

V_F

RRM 90%

RRM 100%

t (µs)

Copyright Vincotech

26

20 Aug. 2021 / Revision 4

10-E206PMA050SA-L184A38Z

datasheet

Ordering Code

Marking

Version

Ordering Code

Without thermal paste

10-E206PMA050SA-L184A38Z

10-E206PMA050SA-L184A38Z-/3/

With thermal paste (3,4 W/mK, PSX-P7)

Name

Date code

UL & VIN

Lot

Serial

Text

NN-NNNNNNNNNNNNNN-

TTTTTTVV

WWYY

UL VIN

LLLLL

SSSS

Type&Ver

Lot number

Serial

Date code

Datamatrix

TTTTTTTVV

LLLLL

SSSS

WWYY

Outline

Pin table [mm]

1

X

Y

Function

ACIn2

ACIn1

DC+Rect

DC-Rect

G27

25,6

22,4

16

12,8

9,6

0

6,4

9,6

0

2

3

4

5

6

3,2

0

7

8

0

3,2

16

9

0

10

11

12

13

14

15

16

17

18

19

20

21

22

23

24

25

26

27

28

29

30

31

32

33

34

35

0

19,2

22,4

25,6

28,8

32

DC-Br

G11

0

DC-1

G13

0

35,2

38,4

41,6

44,8

48

DC-2

G15

0

DC-3

Therm1

Therm2

G16

0

9,6

19,2

28,8

32

22,4

9,6

48

Ph3

44,8

35,2

32

Ph3

G14

Ph2

28,8

19,2

16

Ph2

G12

Ph1

12,8

3,2

0

Ph1

ACIn3

DC+Inv

Br

19,2

16

19,2

Copyright Vincotech

27

20 Aug. 2021 / Revision 4

10-E206PMA050SA-L184A38Z

datasheet

Pinout

DC+Rect

5,6

DC+Inv

33,34

T12

T14

T16

D32

D34

D36

D11

D13

D15

28

G12

25

22

G16

D27

G14

Ph1

29,30

ACIn1

ACIn2

ACIn3

35

3,4

1,2

Ph2

26,27

Br

Ph3

23,24

31,32

T11

T13

T15

T27

D12

D14

D16

D31

D33

D35

11

14

17

9

G11

G13

G15

G27

Rt

7,8

10

DC-Br

12,13

DC-1

15,16

DC-2

18,19

DC-3

20

Therm1

21

DC-Rect

Therm2

---

Identification

Component

Voltage

Current

Function

Comment

ID

T11, T12, T13, T14,

IGBT

600 V

50 A

Inverter Switch

T15, T16

D11, D12, D13, D14,

FWD

50 A

Inverter Diode

D15, D16

T27

IGBT

FWD

600 V

50 A

20 A

Brake Switch

Brake Diode

D27

D31, D32, D33, D34,

D35, D36

Rectifier

NTC

1600 V

35 A

Rectifier Diode

Thermistor

Rt

Copyright Vincotech

28

20 Aug. 2021 / Revision 4

10-E206PMA050SA-L184A38Z

datasheet

Packaging instruction

Handling instruction

Standard packaging quantity (SPQ) 100

>SPQ

Standard

<SPQ

Sample

Handling instructions for flow E1 packages see vincotech.com website.

Package data

Package data for flow E1 packages see vincotech.com website.

Vincotech thermistor reference

See Vincotech thermistor reference table at vincotech.com website.

UL recognition and file number

This device is certified according to UL 1557 standard, UL file number E192116. For more information see vincotech.com website.

Document No.:

Date:

Modification:

Pages

New datasheet format, separate solder and pressfit pin

variant

Update characteristics of rectifier diode, leakage current

max value from 50 -> 100 uA

10-E206PMA050SA-L184A38Z-D4-14

20 Aug. 2021

DISCLAIMER

The information, specifications, procedures, methods and recommendations herein (together “information”) are presented by Vincotech to

reader in good faith, are believed to be accurate and reliable, but may well be incomplete and/or not applicable to all conditions or situations

that may exist or occur. Vincotech reserves the right to make any changes without further notice to any products to improve reliability,

function or design. No representation, guarantee or warranty is made to reader as to the accuracy, reliability or completeness of said

information or that the application or use of any of the same will avoid hazards, accidents, losses, damages or injury of any kind to persons

or property or that the same will not infringe third parties rights or give desired results. It is reader’s sole responsibility to test and determine

the suitability of the information and the product for reader’s intended use.

LIFE SUPPORT POLICY

Vincotech products are not authorised for use as critical components in life support devices or systems without the express written approval

of Vincotech.

As used herein:

1. Life support devices or systems are devices or systems which, (a) are intended for surgical implant into the body, or (b) support or

sustain life, or (c) whose failure to perform when properly used in accordance with instructions for use provided in labelling can be

reasonably expected to result in significant injury to the user.

2. A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to cause

the failure of the life support device or system, or to affect its safety or effectiveness.

Copyright Vincotech

29

20 Aug. 2021 / Revision 4


型号：	10-E206PMA050SA-L184A38Z
厂家：	VINCOTECH
描述：	Easy paralleling;Low turn-off losses;Low collector emitter saturation voltage;Positive temperature coefficient;Short tail current
文件：	总29页 (文件大小：9129K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

10-E206PMA050SA-L184A38Z [VINCOTECH]

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