V23990 P586 x2x D2 19

V23990-P586-*2*-PM
Output Inverter Application
flow1
600V/50A
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)
90
Ploss (W)
Ploss (W)
120
80
100
Mi*cosf i= -1
Mi*cosfi = 1
70
60
80
50
60
40
30
40
20
20
10
Mi*cosfi = 1
Mi*cosfi = -1
0
0
0
At
Tj =
10
20
30
40
50
60
70
Iout (A)
0
80
At
Tj =
°C
125
Mi*cosφ from -1 to 1 in steps of 0,2
20
125
30
40
50
60
70
Iout (A)
80
°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)
40,0
Ploss (W)
Ploss (W)
10
35,0
Ploss = f(Iout)
7,0
6,0
fsw = 16kHz
fsw = 16kHz
30,0
5,0
25,0
4,0
20,0
3,0
15,0
2,0
10,0
1,0
5,0
fsw = 2kHz
fsw = 2kHz
0,0
0,0
0
10
20
30
40
50
At
Tj =
125
DC link =
fsw from
320
V
2 kHz to 16 kHz in steps of factor 2
copyright by Vincotech
60
70Iout (A)
0
80
°C
1
10
20
30
40
50
At
Tj =
125
DC link =
fsw from
320
V
2 kHz to 16 kHz in steps of factor 2
60
70
Iout (A)
80
°C
Revision: 2
V23990-P586-*2*-PM
Output Inverter Application
flow1
Phase
Figure 5
Typical available 50Hz output current
as a function Mi*cosφ
Typical available 50Hz output current
as a function of switching frequency
Iout = f(Mi*cos φ)
Iout (A)
Iout (A)
Phase
Figure 6
70
Th = 60°C
60
600V/50A
Iout = f(fsw)
70
Th = 60°C
60
50
50
40
40
Th = 100°C
30
30
20
20
10
10
Th = 100°C
0
0
-1,0
-0,8
-0,6
-0,4
-0,2
0,0
0,2
At
Tj =
125
DC link =
fsw =
Th from
320
V
4
kHz
60 °C to 100 °C in steps of 5 °C
0,4
0,6
1
0,8
1,0
Mi*cos φ
At
Tj =
°C
10
125
fsw (kHz)
100
°C
DC link = 320
V
Mi*cos φ = 0,8
Th from
60 °C to 100 °C in steps of 5 °C
Phase
Figure 7
Phase
Figure 8
Typical available 50Hz output current as a function of
Iout = f(fsw, Mi*cos φ)
Mi*cos φ and switching frequency
Typical available 0Hz output current as a function
Ioutpeak = f(fsw)
of switching frequency
60
Iout (Apeak)
-1,00
-0,80
50
-0,60
Th = 60°C
Iout (A)
-0,40
37,0-40,0
34,0-37,0
31,0-34,0
0,00
28,0-31,0
0,20
25,0-28,0
0,40
Mi*cosfi
40
-0,20
30
20
22,0-25,0
0,60
10
0,80
Th = 100°C
0
1,00
1
2
4
8
16
32
64
1
fsw
(kHz)
10
At
Tj =
125
°C
At
Tj =
125
DC link =
Th =
320
80
V
°C
DC link =
Th from
320
V
60 °C to 100 °C in steps of 5 °C
Mi =
0
copyright by Vincotech
2
fsw (kHz)
100
°C
Revision: 2
V23990-P586-*2*-PM
Output Inverter Application
flow1
Inverter
Figure 9
Inverter
Figure 10
Typical efficiency as a function of output power
efficiency=f(Pout)
efficiency (%)
Typical available peak output power as a function of
Pout=f(Th)
heatsink temperature
Pout (kW)
600V/50A
18,0
16,0
100,0
2kHz
99,0
2kHz
98,0
14,0
97,0
12,0
96,0
16kHz
10,0
95,0
16kHz
8,0
94,0
6,0
93,0
4,0
92,0
2,0
91,0
0,0
90,0
60
65
70
75
80
85
At
Tj =
125
DC link =
Mi =
cos φ=
fsw from
320
V
1
0,80
2 kHz to 16 kHz in steps of factor 2
90
95
100
Th ( o C)
0
°C
5
10
15
At
Tj =
125
DC link =
Mi =
cos φ=
fsw from
320
V
1
0,80
2 kHz to 16 kHz in steps of factor 2
20
Pout (kW)
25
°C
Inverter
Figure 11
Overload (%)
Typical available overload factor as a function of
Ppeak / Pnom=f(Pnom,fsw)
motor power and switching frequency
400
350
300
250
200
150
Switching frequency (kHz)
Motor nominal power (HP/kW)
100
5,00 / 3,68
7,50 / 5,52
10,00 / 7,36
15,00 / 11,03
20,00 / 14,71
25,00 / 18,39
1
319
213
160
0
0
0
2
314
210
157
0
0
0
4
305
203
152
0
0
0
8
286
191
143
0
0
0
16
252
168
126
0
0
0
At
Tj =
125
°C
DC link =
Mi =
320
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: 2