10 Fx062PA150SA P995F0x P1 14

FZ06 / F0062PA150SA
preliminary datasheet
flowPHASE0
600V/150A
Features
flow0 housing
● Trench Fieldstop IGBT technology
● 2-clip housing in 12mm and 17mm height
● Compact and low inductance design
3
Target Applications
Schematic
● Motor Drive
● UPS
Types
● FZ062PA150SA
● F0062PA150SA
Maximum Ratings
Tj=25°C, unless otherwise specified
Parameter
Condition
Symbol
Value
Unit
600
V
86
113
A
450
A
125
189
W
±20
V
6
360
μs
V
175
°C
600
V
71
98
A
450
A
85
129
W
175
°C
Inverter Transistor
Collector-emitter break down voltage
DC collector current
Repetitive peak collector current
VCE
IC
ICpulse
Power dissipation per IGBT
Ptot
Gate-emitter peak voltage
VGE
Short circuit ratings
tSC
VCC
Maximum Junction Temperature
Tj=Tjmax
Th=80°C
Tc=80°C
tp limited by Tjmax
Tj=Tjmax
Th=80°C
Tc=80°C
Tj≤150°C
VGE=15V
Tjmax
Inverter Diode
Peak Repetitive Reverse Voltage
DC forward current
VRRM
Tj=25°C
IF
Tj=Tjmax
Repetitive peak forward current
IFRM
tp limited by Tjmax
Power dissipation per Diode
Ptot
Tj=Tjmax
Maximum Junction Temperature
Copyright by Vincotech
Tjmax
1
Th=80°C
Tc=80°C
Th=80°C
Tc=80°C
Revision: 1
FZ06 / F0062PA150SA
preliminary datasheet
Maximum Ratings
Tj=25°C, unless otherwise specified
Parameter
Condition
Symbol
Value
Unit
Thermal Properties
Storage temperature
Tstg
-40…+125
°C
Operation temperature under switching condition
Top
-40…+(Tjmax - 25)
°C
4000
V
Creepage distance
min 12,7
mm
Clearance
min 12,7
mm
Insulation Properties
Insulation voltage
Copyright by Vincotech
Vis
t=2s
DC voltage
2
Revision: 1
FZ06 / F0062PA150SA
preliminary datasheet
Characteristic Values
Parameter
Conditions
Symbol
VGE [V] or
VGS [V]
Vr [V] or
VCE [V] or
VDS [V]
Value
IC [A] or
IF [A] or
ID [A]
Tj
Unit
Min
Typ
Max
5
5,8
6,5
1
1,61
1,87
2,2
Inverter Transistor
Gate emitter threshold voltage
VGE(th)
Collector-emitter saturation voltage
VCE(sat)
15
Collector-emitter cut-off current incl. Diode
ICES
0
600
Gate-emitter leakage current
IGES
20
0
Integrated Gate resistor
Rgint
Turn-on delay time
td(on)
Rise time
Turn-off delay time
Fall time
VCE=VGE
0,0024
150
tf
Turn-on energy loss per pulse
Eon
Turn-off energy loss per pulse
Eoff
Input capacitance
Cies
Output capacitance
Coss
Reverse transfer capacitance
Crss
Gate charge
QGate
Thermal resistance chip to heatsink per chip
RthJH
Thermal resistance chip to case per chip
RthJC
0,96
700
Rgoff=4 Ω
Rgon=4 Ω
±15
300
150
Tj=25°C
Tj=150°C
Tj=25°C
Tj=150°C
Tj=25°C
Tj=150°C
Tj=25°C
Tj=150°C
Tj=25°C
Tj=150°C
Tj=25°C
Tj=150°C
V
V
mA
nA
Ω
2
tr
td(off)
Tj=25°C
Tj=150°C
Tj=25°C
Tj=150°C
Tj=25°C
Tj=150°C
Tj=25°C
Tj=150°C
231
241
32
37
296
329
81
95
2,03
3
3,88
5,21
ns
mWs
9240
f=1MHz
0
25
576
Tj=25°C
pF
274
Tj=25°C
±15
930
Thermal grease
thickness≤50um
λ = 1 W/mK
nC
0.76
K/W
Inverter Diode
Diode forward voltage
Peak reverse recovery current
VF
IRRM
Reverse recovery time
trr
Reverse recovered charge
Qrr
Peak rate of fall of recovery current
Reverse recovered energy
Rgon=4 Ω
300
±15
di(rec)max
/dt
Erec
Thermal resistance chip to heatsink per chip
RthJH
Thermal resistance chip to case per chip
RthJC
Copyright by Vincotech
50
Thermal grease
thickness≤50um
λ = 1 W/mK
150
Tj=25°C
Tj=150°C
Tj=25°C
Tj=150°C
Tj=25°C
Tj=150°C
Tj=25°C
Tj=150°C
Tj=25°C
Tj=150°C
Tj=25°C
Tj=150°C
1
1,71
1,6
123,92
161,1
108,8
273,1
7,37
15,35
2262
2417
1,62
3,48
2,2
V
A
ns
μC
A/μs
mWs
1,11
K/W
3
Revision: 1
FZ06 / F0062PA150SA
preliminary datasheet
Output Inverter
Output inverter IGBT
Figure 1
Typical output characteristics
IC = f(VCE)
Output inverter IGBT
Figure 2
Typical output characteristics
IC = f(VCE)
IC (A)
450
IC (A)
450
375
375
300
300
225
225
150
150
75
75
0
0
0
At
tp =
Tj =
VGE from
1
2
3
4
V CE (V)
5
0
At
tp =
Tj =
VGE from
350
μs
25
°C
7 V to 17 V in steps of 1 V
Output inverter IGBT
Figure 3
Typical transfer characteristics
IC = f(VGE)
1
2
3
4
5
350
μs
150
°C
7 V to 17 V in steps of 1 V
Output inverter FRED
Figure 4
Typical diode forward current as
a function of forward voltage
IF = f(VF)
150
V CE (V)
IC (A)
IF (A)
450
375
120
300
90
Tj = 25°C
225
Tj = Tjmax-25°C
Tj = Tjmax-25°C
60
150
30
75
Tj = 25°C
0
0
0
At
tp =
VCE =
1
350
10
2
3
4
5
6
7
8
V GE
9 (V)
10
0
At
tp =
μs
V
Copyright by Vincotech
4
0,5
350
1
1,5
2
2,5
V F (V)
3
μs
Revision: 1
FZ06 / F0062PA150SA
preliminary datasheet
Output Inverter
Output inverter IGBT
Figure 5
Typical switching energy losses
as a function of collector current
E = f(IC)
Output inverter IGBT
Figure 6
Typical switching energy losses
as a function of gate resistor
E = f(RG)
10
E (mWs)
E (mWs)
10
Eoff High T
8
Eon High T
8
Eon Low T
Eoff Low T
Eoff High T
6
6
Eon High T
Eoff Low T
4
4
Eon Low T
2
2
0
0
0
50
100
150
200
250
I C (A)
0
300
With an inductive load at
Tj =
°C
25/150
VCE =
300
V
VGE =
±15
V
Rgon =
4
Ω
Rgoff =
4
Ω
4
8
12
RG( Ω )
16
20
With an inductive load at
Tj =
°C
25/150
VCE =
300
V
VGE =
±15
V
IC =
150
A
Output inverter IGBT
Figure 7
Typical reverse recovery energy loss
as a function of collector current
Erec = f(IC)
Output inverter IGBT
Figure 8
Typical reverse recovery energy loss
as a function of gate resistor
Erec = f(RG)
E (mWs)
4
E (mWs)
5
Erec
4
3,2
Tj = Tjmax -25°C
Tj = Tjmax -25°C
Erec
3
2,4
Tj = 25°C
Erec
2
1,6
Tj = 25°C
Erec
1
0,8
0
0
0
50
100
150
200
250
I C (A)
300
0
With an inductive load at
Tj =
25/150
°C
VCE =
300
V
VGE =
±15
V
Rgon =
4
Ω
Copyright by Vincotech
4
8
12
16
RG( Ω )
20
With an inductive load at
Tj =
25/150
°C
VCE =
300
V
VGE =
±15
V
IC =
150
A
5
Revision: 1
FZ06 / F0062PA150SA
preliminary datasheet
Output Inverter
Output inverter IGBT
Figure 9
Typical switching times as a
function of collector current
t = f(IC)
Output inverter IGBT
Figure 10
Typical switching times as a
function of gate resistor
t = f(RG)
t ( μs)
1
t ( μs)
1
tdoff
tdoff
tdon
tdon
tf
0,1
0,1
tf
tr
tr
0,01
0,01
0,001
0,001
0
50
100
150
200
250
I C (A)
300
0
With an inductive load at
Tj =
150
°C
VCE =
300
V
VGE =
±15
V
Rgon =
4
Ω
Rgoff =
4
Ω
4
8
12
16
RG( Ω )
20
With an inductive load at
Tj =
150
°C
VCE =
300
V
VGE =
±15
V
IC =
150
A
Output inverter FRED
Figure 11
Typical reverse recovery time as a
function of collector current
trr = f(IC)
Output inverter FRED
Figure 12
Typical reverse recovery time as a
function of IGBT turn on gate resistor
trr = f(Rgon)
0,5
0,3
t rr( μs)
t rr( μs)
trr
Tj = Tjmax -25°C
trr
0,25
0,4
Tj = Tjmax -25°C
0,2
0,3
0,15
Tj = 25°C
0,2
trr
0,1
Tj = 25°C
trr
0,1
0,05
0
0
0
At
Tj =
VCE =
VGE =
Rgon =
50
25/150
300
±15
4
100
150
200
250
I C (A)
0
300
At
Tj =
VR =
IF =
VGE =
°C
V
V
Ω
Copyright by Vincotech
6
4
25/150
300
150
±15
8
12
16
R g on ( Ω )
20
°C
V
A
V
Revision: 1
FZ06 / F0062PA150SA
preliminary datasheet
Output Inverter
Output inverter FRED
Figure 13
Typical reverse recovery charge as a
function of collector current
Qrr = f(IC)
Output inverter FRED
Figure 14
Typical reverse recovery charge as a
function of IGBT turn on gate resistor
Qrr = f(Rgon)
20
20
Qrr( μC)
Qrr( μC)
Qrr
Tj = Tjmax -25°C
16
Tj = Tjmax -25°C
16
Qrr
12
12
Qrr
Tj = 25°C
8
Tj = 25°C
8
Qrr
4
4
0
0
At 0
At
Tj =
VCE =
VGE =
Rgon =
50
25/150
300
±15
4
100
150
200
250
I C (A)
300
0
4
At
Tj =
VR =
IF =
VGE =
°C
V
V
Ω
Output inverter FRED
Figure 15
Typical reverse recovery current as a
function of collector current
IRRM = f(IC)
8
25/150
300
150
±15
12
16
R g on ( Ω)
20
°C
V
A
V
Output inverter FRED
Figure 16
Typical reverse recovery current as a
function of IGBT turn on gate resistor
IRRM = f(Rgon)
240
IrrM (A)
IrrM (A)
250
200
IRRM
200
Tj = Tjmax -25°C
160
IRRM
150
Tj = Tjmax - 25°C
120
IRRM
Tj = 25°C
100
IRRM
80
Tj = 25°C
50
40
0
0
0
At
Tj =
VCE =
VGE =
Rgon =
50
25/150
300
±15
4
100
150
200
250
I C (A)
0
300
At
Tj =
VR =
IF =
VGE =
°C
V
V
Ω
Copyright by Vincotech
7
4
25/150
300
150
±15
8
12
16
R gon ( Ω )
20
°C
V
A
V
Revision: 1
FZ06 / F0062PA150SA
preliminary datasheet
Output Inverter
Output inverter FRED
Figure 17
Typical rate of fall of forward
and reverse recovery current as a
function of collector current
dI0/dt,dIrec/dt = f(IC)
10000
dI0/dt
direc / dt (A/ μs)
7000
direc / dt (A/μ s)
Output inverter FRED
Figure 18
Typical rate of fall of forward
and reverse recovery current as a
function of IGBT turn on gate resistor
dI0/dt,dIrec/dt = f(Rgon)
dIo/dtLow T
dIrec/dt
6000
dI0/dt
dIrec/dt
8000
Tj = 25°C
5000
di0/dtHigh T
Tj = Tjmax - 25°C
6000
4000
3000
4000
2000
dIrec/dtLow T
dIrec/dtHigh T
2000
dIrec/dtHigh T
1000
0
0
0
At
Tj =
VCE =
VGE =
Rgon =
50
25/150
300
±15
4
100
150
200
250
I C (A) 300
0
At
Tj =
VR =
IF =
VGE =
°C
V
V
Ω
Output inverter IGBT
Figure 19
IGBT transient thermal impedance
as a function of pulse width
ZthJH = f(tp)
4
25/150
300
150
±15
8
12
20
°C
V
A
V
Output inverter FRED
Figure 20
FRED transient thermal impedance
as a function of pulse width
ZthJH = f(tp)
101
ZthJH (K/W)
Zth-JH (K/W)
101
R gon ( Ω )
16
100
100
D = 0,5
0,2
0,1
0,05
0,02
0,01
0,005
0.000
-1
10
D = 0,5
0,2
0,1
0,05
0,02
0,01
0,005
0.000
10-1
-2
10
10-2
10-5
At
D=
RthJH =
10-4
10-3
10-2
10-1
100
t p (s)
10-5
1011
At
D=
RthJH =
tp / T
0,76
K/W
10-4
10-3
1,11
R (C/W)
0,03
0,15
0,38
0,13
0,04
0,02
R (C/W)
0,04
0,22
0,55
0,20
0,06
0,05
8
100
t p (s)
1011
K/W
FRED thermal model values
Copyright by Vincotech
10-1
tp / T
IGBT thermal model values
Tau (s)
9,6E+00
1,3E+00
2,7E-01
5,3E-02
8,1E-03
4,4E-04
10-2
Tau (s)
9,8E+00
9,7E-01
1,9E-01
3,6E-02
5,3E-03
3,7E-04
Revision: 1
FZ06 / F0062PA150SA
preliminary datasheet
Output Inverter
Output inverter IGBT
Figure 21
Power dissipation as a
function of heatsink temperature
Ptot = f(Th)
Output inverter IGBT
Figure 22
Collector current as a
function of heatsink temperature
IC = f(Th)
150
IC (A)
Ptot (W)
250
200
120
150
90
100
60
50
30
0
0
0
At
Tj =
50
175
100
°C
150
T h ( o C)
200
0
At
Tj =
VGE =
single heating
overall heating
Output inverter FRED
Figure 23
Power dissipation as a
function of heatsink temperature
Ptot = f(Th)
50
175
15
100
T h ( o C)
200
°C
V
Output inverter FRED
Figure 24
Forward current as a
function of heatsink temperature
IF = f(Th)
150
Ptot (W)
IF (A)
200
150
160
120
120
90
80
60
40
30
0
0
0
At
Tj =
50
175
100
°C
Copyright by Vincotech
150
T h ( o C)
200
0
At
Tj =
single heating
overall heating
9
50
175
100
150
T h ( o C)
200
°C
Revision: 1
FZ06 / F0062PA150SA
preliminary datasheet
Output Inverter
Output inverter IGBT
Figure 25
Safe operating area as a function
of collector-emitter voltage
IC = f(VCE)
Output inverter IGBT
Figure 26
Gate voltage vs Gate charge
VGE = f(QGE)
VGE (V)
IC (A)
22
10uS
20
100uS
18
3
10
120V
16
1mS
DC
480V
14
100mS
10mS
102
12
10
101
8
6
4
0
10
2
0
10-1 0
10
At
D=
Th =
VGE =
Tj =
10
1
10
2
V CE (V)
0
103
400
600
800
1000
1200
Q g (nC)
At
IC =
single pulse
80
ºC
±15
V
Tjmax
ºC
Copyright by Vincotech
200
10
150
A
Revision: 1
FZ06 / F0062PA150SA
preliminary datasheet
Switching Definitions Output Inverter
General conditions
= 150 °C
Tj
= 4Ω
Rgon
Rgoff
= 4Ω
Output inverter IGBT
Figure 1
Turn-on Switching Waveforms & definition of tdon, tEon
(tEon = integrating time for Eon)
140
210
%
%
120
tdoff
Output inverter IGBT
Figure 2
Turn-off Switching Waveforms & definition of tdoff, tEoff
(tEoff = integrating time for Eoff)
VCE
IC
170
100
VGE 90%
VCE 90%
80
130
IC
VCE
60
90
tEoff
40
VGE
tdon
20
50
VGE
0
IC10%
IC 1%
VCE 3%
VGE10%
10
-20
tEon
-40
-0,2
-0,05
0,1
0,25
0,4
0,55
-30
0,7
2,8
time (us)
VGE (0%) =
VGE (100%) =
VC (100%) =
IC (100%) =
tdoff =
tEoff =
-15
15
300
150
0,33
0,60
2,95
VGE (0%) =
VGE (100%) =
VC (100%) =
IC (100%) =
tdon =
tEon =
V
V
V
A
μs
μs
Output inverter IGBT
Figure 3
3,1
3,25
-15
15
300
150
0,24
0,44
V
V
V
A
μs
μs
3,4
3,7
time(us)
Output inverter IGBT
Figure 4
Turn-off Switching Waveforms & definition of tf
3,55
Turn-on Switching Waveforms & definition of tr
140
210
%
fitted
%
120
IC
VCE
170
100
IC 90%
130
80
VCE
IC 60%
60
IC90%
90
IC 40%
40
tr
50
20
IC10%
0
10
tf
-20
0,2
0,25
0,3
0,35
0,4
-30
2,95
0,45
time (us)
VC (100%) =
IC (100%) =
tf =
300
150
0,09
Copyright by Vincotech
Ic
IC10%
3,1
3,25
3,4
3,55
3,7
time(us)
VC (100%) =
IC (100%) =
tr =
V
A
μs
11
300
150
0,04
V
A
μs
Revision: 1
FZ06 / F0062PA150SA
preliminary datasheet
Switching Definitions Output Inverter
Output inverter IGBT
Figure 5
Output inverter IGBT
Figure 6
Turn-off Switching Waveforms & definition of tEoff
Turn-on Switching Waveforms & definition of tEon
120
120
%
Poff
%
Eoff
100
100
80
80
60
60
40
40
20
20
Eon
Pon
VGE 10%
VCE 3%
VGE 90%
0
0
tEoff
tEon
IC 1%
-20
-20
-0,2
-0,05
0,1
0,25
0,4
0,55
2,9
0,7
3
3,1
3,2
3,3
3,4
3,5
Poff (100%) =
Eoff (100%) =
tEoff =
45,00
5,23
0,60
Pon (100%) =
Eon (100%) =
tEon =
kW
mJ
μs
Figure 7
Gate voltage vs Gate charge (measured)
3,6
time(us)
time (us)
Output inverter FRED
45,00
3,02
0,44
kW
mJ
μs
Output inverter IGBT
Figure 8
Turn-off Switching Waveforms & definition of trr
20
VGE (V)
120
%
15
Id
80
trr
10
fitted
40
5
Vd
0
0
IRRM10%
-5
-40
-10
-80
IRRM90%
-15
IRRM100%
-20
-200
-120
0
200
400
600
800
1000
1200
1400
1600
3,1
1800
3,2
3,3
3,4
Qg (nC)
VGEoff =
VGEon =
VC (100%) =
IC (100%) =
Qg =
-15
15
300
150
5363,18
Copyright by Vincotech
Vd (100%) =
Id (100%) =
IRRM (100%) =
trr =
V
V
V
A
nC
12
300
150
-161
0,16
3,5
3,6
time(us)
3,7
V
A
A
μs
Revision: 1
FZ06 / F0062PA150SA
preliminary datasheet
Switching Definitions Output Inverter
Output inverter FRED
Figure 9
Output inverter FRED
Figure 10
Turn-on Switching Waveforms & definition of tQrr
(tQrr = integrating time for Qrr)
Turn-on Switching Waveforms & definition of tErec
(tErec= integrating time for Erec)
120
150
%
Erec
%
Qrr
100
100
Id
80
50
tQrr
tErec
60
0
40
-50
20
Prec
-100
0
-20
-150
3,1
3,25
3,4
3,55
3,7
3,85
3,1
4
3,25
3,4
3,55
45,00
2,95
0,55
kW
mJ
μs
time(us)
Id (100%) =
Qrr (100%) =
tQrr =
150
13,55
0,55
Copyright by Vincotech
Prec (100%) =
Erec (100%) =
tErec =
A
μC
μs
13
3,7
3,85
time(us)
4
Revision: 1
FZ06 / F0062PA150SA
preliminary datasheet
Ordering Code and Marking - Outline - Pinout
Ordering Code & Marking
Version
Ordering Code
in DataMatrix as
in packaging barcode as
without thermal paste 12mm housing
without thermal paste 17mm housing
10-FZ062PA150SC-P995F08
10-F0062PA150SC-P995F09
P995F08
P995F09
P995F08
P995F09
Outline
Pinout
Copyright by Vincotech
14
Revision: 1
FZ06 / F0062PA150SA
preliminary datasheet
PRODUCT STATUS DEFINITIONS
Datasheet Status
Target
Preliminary
Final
Product Status
Definition
Formative or In Design
This datasheet contains the design specifications for
product development. Specifications may change in any
manner without notice. The data contained is exclusively
intended for technically trained staff.
First Production
This datasheet contains preliminary data, and
supplementary data may be published at a later date.
Vincotech reserves the right to make changes at any time
without notice in order to improve design. The data
contained is exclusively intended for technically trained
staff.
Full Production
This datasheet contains final specifications. Vincotech
reserves the right to make changes at any time without
notice in order to improve design. The data contained is
exclusively intended for technically trained staff.
DISCLAIMER
The information given in this datasheet describes the type of component and does not represent assured characteristics. For tested
values please contact Vincotech.Vincotech reserves the right to make changes without further notice to any products herein to improve
reliability, function or design. Vincotech does not assume any liability arising out of the application or use of any product or circuit
described herein; neither does it convey any license under its patent rights, nor the rights of others.
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 by Vincotech
15
Revision: 1