INFINEON SKW20N60HS

SKW20N60HS
^
High Speed IGBT in NPT-technology
C
• 30% lower Eoff compared to previous generation
• Short circuit withstand time – 10 µs
G
E
• Designed for operation above 30 kHz
• NPT-Technology for 600V applications offers:
- parallel switching capability
- moderate Eoff increase with temperature
- very tight parameter distribution
•
•
•
•
PG-TO-247-3-21
High ruggedness, temperature stable behaviour
Pb-free lead plating; RoHS compliant
1
Qualified according to JEDEC for target applications
Complete product spectrum and PSpice Models : http://www.infineon.com/igbt/
Type
SKW20N60HS
VCE
IC
Eoff
600V
20
240µJ
Tj
Marking
150°C K20N60HS
Package
PG-TO-247-3-21
Maximum Ratings
Parameter
Symbol
Collector-emitter voltage
VCE
DC collector current
IC
Value
600
Unit
V
A
TC = 25°C
36
TC = 100°C
20
Pulsed collector current, tp limited by Tjmax
ICpul s
80
Turn off safe operating area
-
80
VCE ≤ 600V, Tj ≤ 150°C
IF
Diode forward current
TC = 25°C
40
TC = 100°C
20
Diode pulsed current, tp limited by Tjmax
IFpul s
80
Gate-emitter voltage static
transient (tp<1µs, D<0.05)
VGE
±20
±30
V
tSC
10
µs
Ptot
178
W
Operating junction and storage temperature
Tj ,
Tstg
-55...+150
°C
Time limited operating junction temperature for t < 150h
Tj(tl)
175
Soldering temperature, 1.6mm (0.063 in.) from case for 10s
-
260
2)
Short circuit withstand time
VGE = 15V, VCC ≤ 600V, Tj ≤ 150°C
Power dissipation
TC = 25°C
1
2)
J-STD-020 and JESD-022
Allowed number of short circuits: <1000; time between short circuits: >1s.
Power Semiconductors
1
Rev. 2.2
June 06
SKW20N60HS
^
Thermal Resistance
Parameter
Symbol
Conditions
Max. Value
Unit
RthJC
0.7
K/W
RthJCD
1.7
RthJA
40
Characteristic
IGBT thermal resistance,
junction – case
Diode thermal resistance,
junction – case
Thermal resistance,
junction – ambient
Electrical Characteristic, at Tj = 25 °C, unless otherwise specified
Parameter
Symbol
Conditions
Value
min.
Typ.
max.
600
-
-
T j =2 5 °C
2.8
3.15
T j =1 5 0° C
3.5
4.00
Unit
Static Characteristic
Collector-emitter breakdown voltage
V ( B R ) C E S V G E = 0V , I C = 5 00 µA
Collector-emitter saturation voltage
VCE(sat)
Diode forward voltage
VF
V G E = 15 V , I C = 20 A
V G E = 0V , I F = 2 0 A
T j =2 5 °C
1.5
2.0
T j =1 5 0° C
-
1.5
2.0
3
4
5
Gate-emitter threshold voltage
VGE(th)
I C = 50 0 µA , V C E = V G E
Zero gate voltage collector current
ICES
V C E = 60 0 V, V G E = 0 V
µA
T j =2 5 °C
-
-
40
T j =1 5 0° C
-
-
2500
100
Gate-emitter leakage current
IGES
V C E = 0V , V G E =2 0 V
-
-
Transconductance
gfs
V C E = 20 V , I C = 20 A
-
14
Power Semiconductors
V
2
Rev. 2.2
nA
S
June 06
SKW20N60HS
^
Dynamic Characteristic
Input capacitance
Ciss
V C E = 25 V ,
-
1100
Output capacitance
Coss
V G E = 0V ,
-
150
Reverse transfer capacitance
Crss
f= 1 MH z
-
64
Gate charge
QGate
V C C = 48 0 V, I C =2 0 A
-
100
nC
-
13
nH
-
170
A
pF
V G E = 15 V
LE
Internal emitter inductance
measured 5mm (0.197 in.) from case
Short circuit collector current
1)
IC(SC)
V G E = 15 V ,t S C ≤ 10 µs
V C C ≤ 6 0 0 V,
T j ≤ 1 5 0° C
Switching Characteristic, Inductive Load, at Tj=25 °C
Parameter
Symbol
Conditions
Value
min.
typ.
-
18
-
15
-
207
-
13
-
0.39
-
0.30
-
0.69
max.
Unit
IGBT Characteristic
Turn-on delay time
td(on)
Rise time
tr
Turn-off delay time
td(off)
Fall time
tf
Turn-on energy
Eon
Turn-off energy
Eoff
Total switching energy
Ets
T j =2 5 °C ,
V C C = 40 0 V, I C = 2 0 A,
V G E = 0/ 15 V ,
R G = 16 Ω
2)
L σ = 60 n H,
2)
C σ = 40 pF
Energy losses include
“tail” and diode
reverse recovery.
trr
T j =2 5 °C ,
-
130
tS
V R = 4 00 V , I F = 2 0 A,
-
15
tF
d i F / d t =1 1 00 A / µs
-
115
ns
mJ
Anti-Parallel Diode Characteristic
Diode reverse recovery time
ns
Diode reverse recovery charge
Qrr
-
730
nC
Diode peak reverse recovery current
Irrm
-
16
A
Diode peak rate of fall of reverse
recovery current during t b
d i r r /d t
-
540
A/µs
1)
2)
Allowed number of short circuits: <1000; time between short circuits: >1s.
Leakage inductance L σ a nd Stray capacity C σ due to test circuit in Figure E.
Power Semiconductors
3
Rev. 2.2
June 06
SKW20N60HS
^
Switching Characteristic, Inductive Load, at Tj=150 °C
Parameter
Symbol
Conditions
Value
min.
typ.
-
15
-
8.5
-
65
-
35
-
0.46
-
0.24
-
0.7
-
17
-
13
-
222
-
13
-
0.6
-
0.36
-
0.96
max.
Unit
IGBT Characteristic
Turn-on delay time
td(on)
Rise time
tr
Turn-off delay time
td(off)
Fall time
tf
Turn-on energy
Eon
Turn-off energy
Eoff
Total switching energy
Ets
Turn-on delay time
td(on)
Rise time
tr
Turn-off delay time
td(off)
Fall time
tf
Turn-on energy
Eon
Turn-off energy
Eoff
Total switching energy
Ets
T j =1 5 0° C
V C C = 40 0 V, I C = 2 0 A,
V G E = 0/ 15 V ,
R G = 1 6Ω
1)
L σ = 60 n H,
1)
C σ = 40 pF
Energy losses include
“tail” and diode
reverse recovery.
trr
T j =1 5 0° C
-
200
tS
V R = 4 00 V , I F = 2 0 A,
-
25
tF
d i F / d t =1 2 50 A / µs
T j =1 5 0° C
V C C = 40 0 V, I C = 2 0 A,
V G E = 0/ 15 V ,
R G = 2 .2 Ω
1)
L σ = 60 n H,
1)
C σ = 40 pF
Energy losses include
“tail” and diode
reverse recovery.
ns
mJ
ns
mJ
Anti-Parallel Diode Characteristic
Diode reverse recovery time
ns
-
175
Diode reverse recovery charge
Qrr
-
1500
Diode peak reverse recovery current
Irrm
-
21
A
Diode peak rate of fall of reverse
recovery current during t b
d i r r /d t
-
410
A/µs
1)
nC
Leakage inductance L σ a nd Stray capacity C σ due to test circuit in Figure E.
Power Semiconductors
4
Rev. 2.2
June 06
SKW20N60HS
^
100A
80A
tP=4µs
TC=80°C
IC, COLLECTOR CURRENT
IC, COLLECTOR CURRENT
70A
60A
50A
TC=110°C
40A
30A
Ic
20A
10A
50µs
200µs
1ms
1A
Ic
10A
0A
10Hz
15µs
100Hz
1kHz
DC
10kHz
0.1A
1V
100kHz
f, SWITCHING FREQUENCY
Figure 1. Collector current as a function of
switching frequency
(Tj ≤ 150°C, D = 0.5, VCE = 400V,
VGE = 0/+15V, RG = 16Ω)
10V
100V
1000V
VCE, COLLECTOR-EMITTER VOLTAGE
Figure 2. Safe operating area
(D = 0, TC = 25°C,
Tj ≤150°C;VGE=15V)
1 80W
30A
IC, COLLECTOR CURRENT
Ptot, POWER DISSIPATION
1 60W
1 40W
1 20W
1 00W
80W
60W
20A
10A
40W
20W
0W
25 °C
50°C
75 °C
100 °C
0A
25°C
1 25°C
TC, CASE TEMPERATURE
Figure 3. Power dissipation as a function of
case temperature
(Tj ≤ 150°C)
Power Semiconductors
75°C
125°C
TC, CASE TEMPERATURE
Figure 4. Collector current as a function of
case temperature
(VGE ≤ 15V, Tj ≤ 150°C)
5
Rev. 2.2
June 06
SKW20N60HS
^
V G E =20V
50A
V G E =20V
50A
15V
IC, COLLECTOR CURRENT
IC, COLLECTOR CURRENT
15V
13V
40A
11V
9V
30A
7V
5V
20A
10A
0V
2V
4V
9V
30A
7V
5V
20A
0A
6V
T J = -5 5 °C
2 5 °C
1 5 0 °C
40A
20A
0V
2V
4V
6V
8V
VGE, GATE-EMITTER VOLTAGE
Figure 7. Typical transfer characteristic
(VCE=10V)
Power Semiconductors
0V
2V
4V
6V
VCE, COLLECTOR-EMITTER VOLTAGE
Figure 6. Typical output characteristic
(Tj = 150°C)
VCE(sat), COLLECTOR-EMITT SATURATION VOLTAGE
VCE, COLLECTOR-EMITTER VOLTAGE
Figure 5. Typical output characteristic
(Tj = 25°C)
IC, COLLECTOR CURRENT
11V
10A
0A
0A
13V
40A
5,5V
5,0V
I C =40A
4,5V
4,0V
3,5V
I C =20A
3,0V
2,5V
I C =10A
2,0V
1,5V
1,0V
-50°C
0°C
50°C
100°C
150°C
TJ, JUNCTION TEMPERATURE
Figure 8. Typical collector-emitter
saturation voltage as a function of
junction temperature
(VGE = 15V)
6
Rev. 2.2
June 06
SKW20N60HS
^
t d (o ff)
tf
t, SWITCHING TIMES
t, SWITCHING TIMES
1 00ns
td ( o n )
10ns
tr
1ns
0A
10 A
20A
td(on)
tr
tf
100°C
t d(on)
tr
10Ω
20Ω
30Ω
40Ω
5,0V
4,5V
max.
4,0V
3,5V
typ.
3,0V
2,5V
min.
2,0V
1,5V
-50°C
150°C
TJ, JUNCTION TEMPERATURE
Figure 11. Typical switching times as a
function of junction temperature
(inductive load, VCE=400V,
VGE=0/15V, IC=20A, RG=16Ω,
Dynamic test circuit in Figure E)
Power Semiconductors
10 ns
RG, GATE RESISTOR
Figure 10. Typical switching times as a
function of gate resistor
(inductive load, TJ=150°C,
VCE=400V, VGE=0/15V, IC=20A,
Dynamic test circuit in Figure E)
VGE(th), GATE-EMITT TRSHOLD VOLTAGE
t, SWITCHING TIMES
100ns
50°C
tf
0Ω
td(off)
0°C
t d(o ff)
1 ns
30A
IC, COLLECTOR CURRENT
Figure 9. Typical switching times as a
function of collector current
(inductive load, TJ=150°C,
VCE=400V, VGE=0/15V, RG=16Ω,
Dynamic test circuit in Figure E)
10ns
100 ns
0°C
50°C
100°C
150°C
TJ, JUNCTION TEMPERATURE
Figure 12. Gate-emitter threshold voltage as
a function of junction temperature
(IC = 0.5mA)
7
Rev. 2.2
June 06
SKW20N60HS
^
*) E o n in clu de loss es
*) Eon include losses
E ts *
2,0 m J
E on*
1,0 m J
E o ff
0,0 m J
0A
1 0A
20 A
30A
Eon*
Eoff
20Ω
30Ω
40Ω
D=0.5
0.2
-1
10 K/W 0.1
0.05
R,(K/W)
0.1882
0.3214
0.1512
0.0392
0.02
-2
10 K/W
0.01
τ, (s)
0.1137
2.24*10-2
7.86*10-4
9.41*10-5
R1
R2
-3
10 K/W
single pulse
C 1 = τ 1 / R 1 C 2 = τ 2 /R 2
-4
10 K/W
1µs
150°C
TJ, JUNCTION TEMPERATURE
Figure 15. Typical switching energy losses
as a function of junction
temperature
(inductive load, VCE=400V,
VGE=0/15V, IC=20A, RG=16Ω,
Dynamic test circuit in Figure E)
Power Semiconductors
10Ω
RG, GATE RESISTOR
Figure 14. Typical switching energy losses
as a function of gate resistor
(inductive load, TJ=150°C,
VCE=400V, VGE=0/15V, IC=20A,
Dynamic test circuit in Figure E)
ZthJC, TRANSIENT THERMAL RESISTANCE
E, SWITCHING ENERGY LOSSES
0,50mJ
100°C
0Ω
0
Ets*
50°C
E off
0,5 m J
10 K/W
0,75mJ
0,00mJ
0°C
E on *
0,0 m J
IC, COLLECTOR CURRENT
Figure 13. Typical switching energy losses
as a function of collector current
(inductive load, TJ=150°C,
VCE=400V, VGE=0/15V, RG=16Ω,
Dynamic test circuit in Figure E)
0,25mJ
1,0 m J
4 0A
*) Eon include losses
due to diode recovery
E ts *
due to diode recovery
E, SWITCHING ENERGY LOSSES
E, SWITCHING ENERGY LOSSES
d ue to d iode re cov ery
10µs 100µs
1ms
10ms 100ms
tP, PULSE WIDTH
Figure 16. IGBT transient thermal resistance
(D = tp / T)
8
Rev. 2.2
June 06
SKW20N60HS
15V
120V
480V
10V
C os s
100pF
C rs s
5V
0V
10pF
0nC
50nC
100nC
15µs
10µs
5µs
0µs
10V
11V
12V
13V
10V
20V
250A
200A
150A
100A
50A
0A
10V
14V
VGE, GATE-EMITETR VOLTAGE
Figure 19. Short circuit withstand time as a
function of gate-emitter voltage
(VCE=600V, start at TJ=25°C)
Power Semiconductors
0V
VCE, COLLECTOR-EMITTER VOLTAGE
Figure 18. Typical capacitance as a function
of collector-emitter voltage
(VGE=0V, f = 1 MHz)
IC(sc), short circuit COLLECTOR CURRENT
QGE, GATE CHARGE
Figure 17. Typical gate charge
(IC=20 A)
tSC, SHORT CIRCUIT WITHSTAND TIME
C is s
1nF
c, CAPACITANCE
VGE, GATE-EMITTER VOLTAGE
^
12V
14V
16V
18V
VGE, GATE-EMITETR VOLTAGE
Figure 20. Typical short circuit collector
current as a function of gateemitter voltage
(VCE ≤ 600V, Tj ≤ 150°C)
9
Rev. 2.2
June 06
SKW20N60HS
trr, REVERSE RECOVERY TIME
400ns
300ns
IF=40A
200ns
IF=20A
Qrr, REVERSE RECOVERY CHARGE
^
2,0µC
IF=40A
1,5µC
IF=20A
1,0µC
IF=10A
0,5µC
IF=10A
100ns
200A/µs
0,0µC
400A/µs
600A/µs
200A/µs
800A/µs
25A
IF=40A
IF=20A
20A
15A
IF=10A
10A
5A
0A
200A/µs
400A/µs
600A/µs
800A/µs
800A/µs
-400A/µs
-300A/µs
-200A/µs
-100A/µs
-0A/µs
200A/µs
diF/dt, DIODE CURRENT SLOPE
Figure 23. Typical reverse recovery current
as a function of diode current
slope
(VR=400V, TJ=150°C,
Dynamic test circuit in Figure E)
Power Semiconductors
600A/µs
diF/dt, DIODE CURRENT SLOPE
Figure 22. Typical reverse recovery charge
as a function of diode current
slope
(VR=400V, TJ=150°C,
Dynamic test circuit in Figure E)
dirr/dt, DIODE PEAK RATE OF FALL
OF REVERSE RECOVERY CURRENT
Irr, REVERSE RECOVERY CURRENT
diF/dt, DIODE CURRENT SLOPE
Figure 21. Typical reverse recovery time as
a function of diode current slope
(VR=400V, TJ=150°C,
Dynamic test circuit in Figure E)
400A/µs
400A/µs
600A/µs
800A/µs
diF/dt, DIODE CURRENT SLOPE
Figure 24. Typical diode peak rate of fall of
reverse recovery current as a
function of diode current slope
(VR=400V, TJ=150°C,
Dynamic test circuit in Figure E)
10
Rev. 2.2
June 06
SKW20N60HS
^
TJ=-55°C
25°C
150°C
2,0V
VF, FORWARD VOLTAGE
IF, FORWARD CURRENT
30A
20A
10A
1,8V
1,6V
1,4V
1,2V
0A
0,0V
0,5V
1,0V
-50°C
1,5V
ZthJC, TRANSIENT THERMAL RESISTANCE
VF, FORWARD VOLTAGE
Figure 25. Typical diode forward current as
a function of forward voltage
IF=40A
IF=20A
IF=10A
0°C
50°C
100°C
150°C
TJ, JUNCTION TEMPERATURE
Figure 26. Typical diode forward voltage as a
function of junction temperature
0
10 K /W D =0.5
0.2
R,(K/W)
0.311
0.271
0.221
0.584
0.314
0.1
0.05
-1
10 K /W
0.02
R1
τ, (s)
7.83*10-2
1.21*10-2
1.36*10-3
1.53*10-4
2.50*10-5
R2
0.01
C1= τ1/R1
single pulse
C 2 = τ 2 /R 2
-2
10 K /W
1µs
10µs
100µs
1m s
10m s 100m s
tP, PULSE WIDTH
Figure 27. Diode transient thermal
impedance as a function of pulse
width
(D=tP/T)
Power Semiconductors
11
Rev. 2.2
June 06
SKW20N60HS
^
PG-TO247-3-21
Power Semiconductors
12
Rev. 2.2
June 06
SKW20N60HS
^
i,v
tr r =tS +tF
diF /dt
Qr r =QS +QF
IF
tr r
tS
QS
Ir r m
tF
QF
10% Ir r m
dir r /dt
90% Ir r m
t
VR
Figure C. Definition of diodes
switching characteristics
τ1
τ2
r1
τn
r2
rn
Tj (t)
p(t)
r1
r2
rn
Figure A. Definition of switching times
TC
Figure D. Thermal equivalent
circuit
Figure E. Dynamic test circuit
Leakage inductance Lσ =60nH
an d Stray capacity C σ =40pF.
Figure B. Definition of switching losses
Power Semiconductors
13
Rev. 2.2
June 06
SKW20N60HS
^
Edition 2006-01
Published by
Infineon Technologies AG
81726 München, Germany
© Infineon Technologies AG 6/8/06.
All Rights Reserved.
Attention please!
The information given in this data sheet shall in no event be regarded as a guarantee of conditions or
characteristics (“Beschaffenheitsgarantie”). With respect to any examples or hints given herein, any typical
values stated herein and/or any information regarding the application of the device, Infineon Technologies
hereby disclaims any and all warranties and liabilities of any kind, including without limitation warranties of
non-infringement of intellectual property rights of any third party.
Information
For further information on technology, delivery terms and conditions and prices please contact your nearest
Infineon Technologies Office (www.infineon.com).
Warnings
Due to technical requirements components may contain dangerous substances. For information on the types
in question please contact your nearest Infineon Technologies Office.
Infineon Technologies Components may only be used in life-support devices or systems with the express
written approval of Infineon Technologies, if a failure of such components can reasonably be expected to
cause the failure of that life-support device or system, or to affect the safety or effectiveness of that device or
system. Life support devices or systems are intended to be implanted in the human body, or to support
and/or maintain and sustain and/or protect human life. If they fail, it is reasonable to assume that the health
of the user or other persons may be endangered.
Power Semiconductors
14
Rev. 2.2
June 06