10 F006PPA015SB M684B P1 19

10-F006PPA015SB-M684B
preliminary datasheet
Output Inverter Application
flowPIM0+PFC 2nd
600V/15A
General conditions
3phase SPWM
VGEon = 15 V
VGEoff = -15 V
Rgon = 16 Ω
Rgoff = 16 Ω
IGBT
Figure 1
FWD
Figure 2
Typical average static loss as a function of output current
Ploss = f(Iout)
Typical average static loss as a function of output current
Ploss = f(Iout)
Ploss (W)
35
Ploss (W)
40
Mi*cosfi = 1
30
Mi*cosf i= -1
30
25
20
20
15
10
10
5
Mi*cosfi = 1
Mi*cosfi = -1
0
0
5
10
15
20
25
0
30
0
35
5
10
15
20
25
30
At
Tj =
125
At
Tj =
°C
Mi*cosφ from -1 to 1 in steps of 0,2
125
°C
Mi*cosφ from -1 to 1 in steps of 0,2
IGBT
Figure 3
Typical average switching loss
as a function of output current
FWD
Figure 4
Typical average switching loss
as a function of output current
Ploss = f(Iout)
Ploss (W)
16
Ploss (W)
35
Iout (A)
Iout (A)
fsw = 16kHz
14
Ploss = f(Iout)
6
5
fsw = 16kHz
12
4
10
3
8
6
2
4
1
2
fsw = 2kHz
fsw = 2kHz
0
0
0
5
10
15
20
At
Tj =
125
DC link =
fsw from
400
V
2 kHz to 16 kHz in steps of factor 2
copyright by Vincotech
25
30 Iout (A)
0
35
°C
1
5
10
15
20
At
Tj =
125
DC link =
fsw from
400
V
2 kHz to 16 kHz in steps of factor 2
25
30
Iout (A)
35
°C
Revision: 1
10-F006PPA015SB-M684B
preliminary datasheet
Output Inverter Application
flowPIM0+PFC 2nd
Phase
Figure 5
Typical available 50Hz output current
as a function Mi*cosφ
600V/15A
Phase
Figure 6
Typical available 50Hz output current
as a function of switching frequency
Iout = f(Mi*cos φ)
Iout = f(fsw)
25
Iout (A)
Iout (A)
25
Th = 60°C
Th = 100°C
20
Th = 60°C
20
15
15
Th = 100°C
10
10
5
5
0
0
-1,0
-0,5
0,0
0,5
At
Tj =
125
DC link =
fsw =
Th from
400
V
4
kHz
60 °C to 100 °C in steps of 5 °C
1
1,0
Mi*cos φ
At
Tj =
°C
10
125
100
fsw (kHz)
°C
DC link = 400
V
Mi*cos φ = 0,8
Th from
60 °C to 100 °C in steps of 5 °C
Phase
Figure 7
Typical available 0Hz output current as a function
Ioutpeak = f(fsw)
of switching frequency
-1,0
20,0-22,0
25
Iout (Apeak)
-0,8
Mi*cosfi
Iout (A)
Phase
Figure 8
Typical available 50Hz output current as a function of
Iout = f(fsw, Mi*cos φ)
Mi*cos φ and switching frequency
-0,6
Th = 60°C
20
-0,4
18,0-20,0
-0,2
16,0-18,0
15
0,0
0,2
14,0-16,0
10
Th = 100°C
0,4
12,0-14,0
0,6
5
0,8
10,0-12,0
1,0
1
2
4
8
16
32
fsw (kHz)
0
64
1
10
At
Tj =
125
°C
At
Tj =
125
DC link =
Th =
400
80
V
°C
DC link =
Th from
400
V
60 °C to 100 °C in steps of 5 °C
Mi =
0
copyright by Vincotech
2
fsw (kHz)
100
°C
Revision: 1
10-F006PPA015SB-M684B
preliminary datasheet
Output Inverter Application
flowPIM0+PFC 2nd
Inverter
Figure 9
600V/15A
Inverter
Figure 10
Typical available peak output power as a function of
Pout=f(Th)
heatsink temperature
Typical efficiency as a function of output power
efficiency=f(Pout)
efficiency (%)
Pout (kW)
8
2kHz
100
99
2kHz
6
16kHz
98
4
16kHz
97
2
96
0
95
60
70
90
80
At
Tj =
125
DC link =
Mi =
cos φ=
fsw from
400
V
1
0,80
2 kHz to 16 kHz in steps of factor 2
100
Th ( o C)
0
°C
2
4
6
At
Tj =
125
DC link =
Mi =
cos φ=
fsw from
400
V
1
0,80
2 kHz to 16 kHz in steps of factor 2
8
10
Pout (kW)
12
°C
Inverter
Figure 11
Overload (%)
Typical available overload factor as a function of
Ppeak / Pnom=f(Pnom,fsw)
motor power and switching frequency
500
450
400
350
300
250
200
Switching frequency (kHz)
150
Motor nominal power (HP/kW)
100
1,50 / 1,10
2,00 / 1,47
3,00 / 2,21
5,00 / 3,68
7,50 / 5,52
10,00 / 7,36
1
499
374
250
150
0
0
2
499
374
250
150
0
0
4
499
374
250
150
0
0
8
499
374
250
150
0
0
16
499
374
250
150
0
0
At
Tj =
125
°C
DC link =
Mi =
400
1
V
cos φ=
fsw from
Th =
0,8
1 kHz to 16kHz in steps of factor 2
80
°C
Motor eff = 0,85
copyright by Vincotech
3
Revision: 1
10-F006PPA015SB-M684B
preliminary datasheet
Boost PFC Application
flowPIM0+PFC 2nd
600V/15A
General conditions
Boost PFC
VGEon
VGEoff
Rgon
Rgoff
Vin
=
=
=
=
=
10 V
0V
8Ω
8Ω
Vinpk*sinωt
MOSFET
Figure 1
FWD
Figure 2
Typical average static loss as a function of input current
Ploss = f(Iin)
Typical average static loss as a function of input current
Ploss = f(Iin)
50
Ploss (W)
Ploss (W)
150
Vinpk/Vout
=0.1
125
Vinpk/Vout=1
40
100
30
75
20
50
10
25
Vinpk/Vout
=0.1
Vinpk/Vout=1
0
0
0
At
Tj =
5
125
10
15
20
25
30
Iin (A)
35
0
At
Tj =
°C
Vinpk / Vout from 0,1 to 1 in steps of 0,1
125
10
15
20
25
30
Iin (A)
35
°C
Vinpk / Vout from 0,1 to 1 in steps of 0,1
MOSFET
Figure 3
Typical average switching loss
as a function of input current
FWD
Figure 4
Typical average switching loss
as a function of input current
Ploss = f(Iin)
Ploss = f(Iin)
12
120
Ploss (W)
Ploss (W)
5
fsw=160kHz
100
10
fsw=160kHz
80
8
60
6
40
4
20
2
fsw=20kHz
fsw=20kHz
0
0
0
At
Tj =
5
125
10
15
20
25
30
Iin (A)
35
0
At
Tj =
°C
DC link = 400
V
fsw from 20 kHz to 160 kHz in steps of factor 2
copyright by Vincotech
5
125
10
15
20
25
30
Iin (A) 35
°C
DC link = 400
V
fsw from 20 kHz to 160 kHz in steps of factor 2
4
Revision: 1
10-F006PPA015SB-M684B
preliminary datasheet
Boost PFC Application
flowPIM0+PFC 2nd
PFC
Figure 5
Typical available input current
as a function of Vinpk / Vout
600V/15A
PFC
Figure 6
Typical available input current
as a function of switching frequency
Iin = f(Vinpk/Vout)
25
Iin = f(fsw)
Iin (A)
Iin(A)
25
Th=60°C
20
20
Th=60°C
15
15
Th=100°C
10
10
5
5
Th=100°C
0
0,1
0,2
0,3
0,4
0,5
0,6
0,7
0,8
0
0,9
1,0
Vinpk/Vout
10
100
At
Tj =
125
°C
At
Tj =
125
°C
DC link =
fsw =
400
20
V
kHz
DC link = 400
Vinpk/Vout = 0,8
V
Th from 60 °C to 100 °C in steps of 5 °C
fsw (kHz)
1000
Th from 60 °C to 100 °C in steps of 5 °C
PFC
Figure 7
Typical available input current
as a function of switching frequency
0,1
0,3
Iin(A)
0,2
20,0-22,0
Iin = f(fsw)
25
Vinpk/Vout
Iin (A)
PFC
Figure 8
Typical available input current as a function of
of Vinpk / Vout and switching frequency
Iin = f(fsw, Vinpk/Vout)
20
18,0-20,0
0,4
16,0-18,0
Th=60°C
14,0-16,0
15
0,5
12,0-14,0
10,0-12,0
0,6
8,0-10,0
10
0,7
6,0-8,0
4,0-6,0
0,8
5
2,0-4,0
0,9
Th=100°C
10
20
40
80
160
1,0
320
0
10
fsw (kHz)
100
At
Tj =
125
°C
At
Tj =
125
°C
DC link =
Th =
400
80
V
°C
DC link = 400
Vinpk/Vout = 0,4
V
fsw (kHz)
1000
Th from 60 °C to 100 °C in steps of 5 °C
copyright by Vincotech
5
Revision: 1
10-F006PPA015SB-M684B
preliminary datasheet
Boost PFC Application
flowPIM0+PFC 2nd
PFC
Figure 9
PFC
Figure 10
Typical efficiency as a function of input power
efficiency = f(Pin)
efficiency (%)
Typical available electric input power as a function of
Pin = f(Th)
heatsink temperature
5,0
Pin (kW)
600V/15A
20kHz
100
20kHz
99
4,0
98
3,0
97
160kHz
2,0
96
160kHz
1,0
95
0,0
94
60
At
Tj =
70
125
DC link = 400
Vinpk/Vout = 0,8
80
90
Th ( o C)
100
0
1
°C
At
Tj =
V
kHz
DC link = 400
Vinpk/Vout = 0,8
fsw from 20 kHz to 160 kHz in steps of factor 2
125
2
3
4
6
Pin (kW)
7
°C
V
kHz
fsw from 20 kHz to 160 kHz in steps of factor 2
PFC
Figure 11
PFC
Figure 12
Typical available electric input power as a function of
Pin = f(Th)
heatsink temperature
Typical efficiency as a function of input power
efficiency = f(Pin)
100
efficiency (%)
Pin (kW)
2,5
2,0
98
20kHz
20kHz
1,5
96
1,0
94
160kHz
160kHz
92
0,5
90
0,0
60
At
Tj =
5
70
80
125
°C
DC link = 400
Vinpk/Vout = 0,4
V
90
Th ( o C)
0,0
100
1,0
1,5
2,0
2,5
3,0
3,5
Pin (kW)
At
Tj =
fsw from 20 kHz to 160 kHz in steps of factor 2
copyright by Vincotech
0,5
125
°C
DC link = 400
Vinpk/Vout = 0,4
V
fsw from 20 kHz to 160 kHz in steps of factor 2
6
Revision: 1
10-F006PPA015SB-M684B
preliminary datasheet
Boost PFC Application
flowPIM0+PFC 2nd
Rectifier
Figure 13
600V/15A
Rectifier Bridge
Figure 14
Typical efficiency as a function of input power
efficiency = f(Pin)
efficiency (%)
Typical average static loss as a function of input current
Ploss = f(Iin)
Ploss (W)
20
100
Vinpk/Vout=
0,8
99
15
Vinpk/Vout=
0,4
98
10
97
5
96
0
95
0
5
At
Tj =
10
15
20
25
30
Iin (A)
35
0
At
Tj =
°C
125
Overall
Figure 15
125
4
6
Pin (kW)
8
°C
Overall
Figure 16
Typical efficiency as a function of input power
efficiency = f(Pin)
Typical efficiency as a function of input power
efficiency = f(Pin)
100
efficiency (%)
100
efficiency (%)
2
20kHz
98
98
96
160kHz
96
94
160kHz
92
94
90
20kHz
92
88
86
90
0
At
Tj =
2
125
DC link = 400
Vinpk/Vout = 0,8
4
6
Pin (kW)
0
8
2
3
4
Pin (kW)
°C
At
Tj =
°C
V
kHz
DC link = 400
Vinpk/Vout = 0,4
V
kHz
fsw from 20 kHz to 160 kHz in steps of factor 2
copyright by Vincotech
1
fsw from 20 kHz to 160 kHz in steps of factor 2
7
Revision: 1