70 W624N3A1K2SC L400FP D1 19

70-W624N3A1K2SC-L400FP
Application sheet
NPC Application
flow NPC 12w
2400 V / 1200 A
General conditions
BUCK
=
=
=
=
V GEon
V GEoff
R gon
R goff
15 V
-10 V
0,3 Ω
0,3 Ω
Figure 1.
V out= 400 VAC
Buck T1, T4 / D5, D6 IGBT
BOOST
=
=
=
=
V GEon
V GEoff
R gon
R goff
Figure 2.
Typical average static loss as a function of
output current IoRMS
15 V
-10 V
0,9 Ω
0,9 Ω
Buck T1, T4 / D5, D6 FWD
Typical average static loss as a function of
output current IoRMS
P loss=f(I out)
1400
●UPS
Ploss (W)
Ploss (W)
800
φ=0º
φ=90º
700
1200
600
1000
500
800
400
600
300
400
φ=0º
200
200
100
φ=180º
0
0
0
200
400
600
Conditions:
T j=
125
parameter:
φ
from
800
1000
1200
I out (A)
1400
0
°C
0°
12
in
Figure 3.
to
steps
180°
200
400
600
Conditions:
T j=
125
parameter:
φ
from
800
Buck T1, T4 / D5, D6 IGBT
1200
I out (A)
1400
°C
0°
12
in
Figure 4.
Typical average static loss as a function of
phase displacement φ
P loss=f(φ )
1000
to
steps
180°
Buck T1, T4 / D5, D6 FWD
Typical average static loss as a function of
phase displacement φ
P loss=f(φ )
800
Ploss (W)
Ploss (W)
1400
IoutRMS=Imax
IoutRMS=Imax
700
1200
600
1000
500
800
400
600
300
400
200
200
100
IoutRMS=6% Imax
IoutRMS=6%Imin
0
0
0
Conditions:
parameter:
50
T j=
I oRMS
100
125
from
in steps of
copyright Vincotech
150
°C
79,2 A
158
to
φ( º )
200
0
Conditions:
parameter:
1187 A
A
50
T j=
I oRMS
100
125
from
in steps of
1
°C
79,2 A
158
150
φ( º )
200
to
1187 A
A
08 Dec. 2015 / Revision 1
70-W624N3A1K2SC-L400FP
Application sheet
NPC Application
flow NPC 12w
Figure 5.
Buck T1, T4 / D5, D6 IGBT
2400 V / 1200 A
Figure 6.
Buck T1, T4 / D5, D6 FWD
Typical average switching loss as a function of
Typical average switching loss as a function of
phase displacement φ
P loss=f(φ )
phase displacement φ
P loss=f(φ )
250
Ploss (W)
Ploss (W)
500
450
IoutRMS=Imax
IoutRMS=Imax
200
400
350
150
300
250
100
200
150
50
100
50
IoutRMS=6% Imax
IoutRMS=6% Imax
0
0
0
parameter:
100
T j=
f sw=
125
8
DC-link=
I oRMS
150
φ( º )
0
200
°C
kHz
1200
from
50
Conditions:
V
79,2 A
in steps of
158
Figure 7.
to
1187 A
parameter:
100
T j=
f sw=
125
8
DC-link=
I oRMS
A
Buck T1, T4 / D5, D6 IGBT
φ( º )
200
°C
kHz
1200
from
V
79,2 A
in steps of
158
Figure 8.
Typical total loss as a function of
phase displacement φ and output current I oRMS
P loss=f(I oRMS;φ )
150
to
1187 A
A
Buck T1, T4 / D5, D6 FWD
Typical total loss as a function of
phase displacement φ and output current I oRMS
P loss=f(I oRMS;φ )
1188
1188
P loss (W)
1600-1800
1030
IoutRMS
P loss (W)
1030
800-900
IoutRMS
Conditions:
50
1400-1600
871
871
700-800
1200-1400
600-700
713
713
1000-1200
500-600
554
800-1000
554
400-500
600-800
396
396
300-400
400-600
238
238
200-300
200-400
0
0-200
15
30
45
60
75
100-200
79
90 105 120 135 150 165 180
0
15
30
45
60
75
79
90 105 120 135 150 165 180
0-100
φ( º )
Conditions:
T j=
DC-link=
f sw=
copyright Vincotech
125
1200
8
φ( º )
°C
Conditions:
V
kHz
T j=
DC-link=
f sw=
2
125
1200
8
°C
V
kHz
08 Dec. 2015 / Revision 1
70-W624N3A1K2SC-L400FP
Application sheet
NPC Application
flow NPC 12w
Figure 9.
for Buck T1, T4 / D5, D6 IGBT+FWD
2400 V / 1200 A
Figure 10.
for Buck T1, T4 / D5, D6 IGBT+FWD
Typical available output current as a function of
phase displacement φ
Typical available output current as a function of
switching frequency fsw
I out=f(φ )
I out=f(f sw)
1400
Iout (A)
Iout (A)
1400
Th=50°C
Th=50°C
1200
1200
1000
1000
800
800
Th=100°C
600
600
Th=100°C
400
400
200
200
0
0
30
60
90
120
150
0
180
0
φ
Conditions:
T j= T jmax-25 °C
f sw=
1200
V
parameter:
Heatsink temp.
50
°C to
T h from
100
in
steps
8 kHz
Conditions:
DC-link=
Figure 11.
10
1
1200
parameter:Heatsink temp.
T h from
50
°C
in
10
fsw (kHz)
100
φ= 0 °
T j= T jmax-25 °C
DC-link=
°C
10
V
°C to
100
°C
steps
°C
for Buck T1, T4 / D5, D6 IGBT+FRED
Typical available 50Hz output current as a function of
fsw and phase displacement φ
I out=f(f sw,φ )
180
I out (A)
165
φ
150
1100-1200
135
120
1000-1100
105
90
900-1000
75
60
45
800-900
30
15
700-800
0
1
1
2
4
8
0
16
fsw (kHz)
Conditions:
T j= T jmax-25 °C
DC-link=
T h=
copyright Vincotech
1200
80
V
°C
3
08 Dec. 2015 / Revision 1
70-W624N3A1K2SC-L400FP
Application sheet
NPC Application
flow NPC 12w
Figure 12.
Boost T2, T3 / D2, D3 IGBT
2400 V / 1200 A
Figure 13.
Boost T2, T3 / D2, D3 FRED
Typical average static loss as a function of
Typical average static loss as a function of
output current
P loss=f(I out)
output current
P loss=f(I out)
1000
Ploss (W)
Ploss (W)
1400
φ=0º
1200
φ=180º
800
1000
600
800
600
400
400
200
200
φ=180º
φ=0º
0
0
0
200
400
600
800
1000
1200
0
Iout (A)
Conditions:
T j=
125
parameter:
φ
from
in
Figure 14.
°C
0°
12
to
steps
180º
Boost T2, T3 / D2, D3 IGBT
200
400
600
Conditions:
T j=
125
parameter:
φ
from
in
Figure 15.
Typical average static loss
as a function of phase displacement
P loss=f(φ )
1000
1200
1400
Iout (A)
°C
0°
12
to
steps
180º
Boost T2, T3 / D2, D3 FRED
Typical average static loss
as a function of phase displacement
P loss=f(φ )
FRED D1
1000
Ploss (W)
1400
Ploss (W)
800
IoutRMS=Imax
IoutRMS=Imax
900
1200
800
1000
700
600
800
500
600
400
300
400
200
200
100
IoutRMS=6% Imax
IoutRMS=6% Imax
0
0
0
Conditions:
parameter:
50
T j=
I oRMS
100
125
from
in steps of
copyright Vincotech
°C
79 A
150
to
φ( º )
200
0
Conditions:
parameter:
1187 A
158 A
50
T j=
I oRMS
100
125
from
in steps of
4
150
°C
79 A
to
φ( º )
200
1187 A
158 A
08 Dec. 2015 / Revision 1
70-W624N3A1K2SC-L400FP
Application sheet
NPC Application
flow NPC 12w
Figure 16.
Boost T2, T3 / D2, D3 IGBT
2400 V / 1200 A
Figure 17.
Boost T2, T3 / D2, D3 FRED
Typical average switching loss as a function of
Typical average switching loss as a function of
phase displacement
P loss=f(φ )
phase displacement
P loss=f(φ )
300
Ploss (W)
Ploss (W)
900
IoutRMS=Imax
800
IoutRMS=Imax
250
700
200
600
500
150
400
100
300
200
IoutRMS=6% Imax
50
100
IoutRMS=6% Imax
0
0
0
50
Conditions:
100
T j=
DC-link=
parameter:
I oRMS
125
°C
1200
from
V
in steps of
Figure 18.
150
φ( º )
f sw=
79 A
to
158 A
A
0
200
8 kHz
50
Conditions:
T j=
DC-link=
parameter:
I oRMS
1187 A
100
150
125
°C
f sw=
8 kHz
1200
from
V
79 A
to
1187 A
158 A
A
in steps of
Boost T2, T3 / D2, D3 IGBT
Figure 19.
200
φ( º )
Boost T2, T3 / D2, D3 FRED
Typical total loss as a function of phase displacement
and IoutRMS
Typical total loss as a function of phase displacement
and IoutRMS
P loss=f(I oRMS;φ )
P loss=f(I oRMS;φ )
1188
1188
P loss (W)
1030
IoutRMS
1030
1200-1400
IoutRMS
P loss (W)
1000-1200
871
871
1000-1200
800-1000
713
713
800-1000
600-800
554
554
600-800
400-600
396
396
400-600
200-400
238
238
200-400
0-200
0
15
30
45
60
75
79
90 105 120 135 150 165 180
0-200
0
15
30
45
60
75
79
90 105 120 135 150 165 180
φ( º )
φ( º )
Conditions:
T j=
DC-link=
f sw=
copyright Vincotech
125
1200
8
°C
Conditions:
V
kHz
T j=
DC-link=
f sw=
5
125
1200
8
°C
V
kHz
08 Dec. 2015 / Revision 1
70-W624N3A1K2SC-L400FP
Application sheet
NPC Application
flow NPC 12w
Figure 20.
Boost T2, T3 / D2, D3 IGBT+FWD
2400 V / 1200 A
Figure 21.
Boost T2, T3 / D2, D3 IGBT+FWD
Typical available output current as a function of
Typical available output current
of phase displacement
I out=f(φ )
as a function of switching frequency
I out=f(f sw)
1400
Iout (A)
Iout (A)
1400
1200
Th=50°C
1200
Th=50°C
1000
1000
800
800
Th=100°C
600
600
Th=100°C
400
400
200
200
0
0
30
60
90
120
150
0
180
0
φ( º )
Conditions:
T j= T jmax-25 °C
f sw=
1200
V
parameter:
Heatsink temp.
50
°C to
T h from
8 kHz
Conditions:
DC-link=
in
Figure 22.
10
1
10
T j= T jmax-25 °C
100
φ = 90°
DC-link=
100
°C
1200
V
parameter:
Heatsink temp.
T h from
50
°C to
f sw (kHz)
°C
steps
in
10
°C
100
°C
steps
Boost T2, T3 / D2, D3 IGBT+FRED
Typical available 50Hz output current as a function of
f sw and phase displacement
I out=f(f sw,φ )
180
I out (A)
165
φ
150
1101-1201
135
1001-1101
120
901-1001
105
90
801-901
75
701-801
60
601-701
45
30
501-601
15
401-501
0,3
0,5
1,0
2,0
4,0
0
8,0 16,0
fsw (kHz)
Conditions:
T j= T jmax-25 °C
DC-link=
T h=
copyright Vincotech
1200
80
V
°C
6
08 Dec. 2015 / Revision 1
70-W624N3A1K2SC-L400FP
Application sheet
NPC Application
flow NPC 12w
Figure 23.
per MODULE
2400 V / 1200 A
Figure 24.
per MODULE
Typical available output current as a function of
Typical available output current
heat sink temperature
I out=f(T h)
as a function of phase displacement
I out=f(φ )
1400
Iout (A)
Iout (A)
1400
1200
1200
250 Hz
Th=50°C
1000
1000
800
800
16 kHz
600
600
400
400
200
200
Th=100°C
0
0
60
70
Conditions:
80
90
T h ( o C)
0
100
parameter:
f sw from
1200
0°
60
Conditions:
V
parameter:
16
120
kHz
T h from
in steps of factor 2
in
Figure 25.
per MODULE
Typical available output current as a function of
switching frequency
I out=f(f sw)
180
1200
8
V
kHz
Heatsink temp.
50
°C to
10
100
°C
steps
Figure 26.
per MODULE
Typical available 50Hz output current as a function of
f sw and phase displacement
I out=f(f sw,φ )
1400
180
I out (A)
Iout (A)
150
T j= T jmax-25 °C
DC-link=
f sw=
Switching freq.
0,25
kHz to
90
φ
T j= T jmax-25 °C
DC-link=
φ=
30
φ
165
Th=50°C
1200
150
1100-1200
135
1000-1100
1000
120
105
900-1000
800
90
800-900
75
Th=100°C
600
60
700-800
45
600-700
400
30
500-600
15
200
400-500
0,3
0,5
1,0
0
2,0
4,0
0
8,0 16,0
f sw (kHz)
0
1
Conditions:
10
T j= T jmax-25 °C
DC-link=
parameter:
100
0°
Conditions:
1200
V
Heatsink temp.
T h from
50
°C to
100
in
10
°C
steps
copyright Vincotech
φ=
f sw (kHz)
T j= T jmax-25 °C
DC-link=
T h=
7
1200
80
V
°C
08 Dec. 2015 / Revision 1
70-W624N3A1K2SC-L400FP
Application sheet
NPC Application
flow NPC 12w
Figure 27.
per MODULE
Figure 28.
Typical efficiency as a function of output power
η=f(Pout)
per MODULE
Typical efficiency as a function of output power
η=f(Pout)
100,0
efficiency (%)
efficiency (%)
2400 V / 1200 A
99,5
100,0
99,5
250 Hz
φ=0º
99,0
99,0
98,5
φ=180º
16 kHz
98,5
98,0
98,0
97,5
97,5
97,0
97,0
96,5
96,5
96,0
0
100
200
300
400
500
0
P out (kVA)
Conditions:
T j=
f sw=
DC-link=
parameter:
125
8
Conditions:
1200
V
phase displacement
f sw from
to
Figure 29.
180 °
300
400
500
125
1200
φ= 0 °
°C
V
Switching freq.
0,25
kHz to
16
kHz
in steps of factor 2
per MODULE
Figure 30.
Typical available output power as a function of
heat sink temperature
P out=f(T h)
Pout (kW)
T j=
DC-link=
parameter:
0°
200
Pout (kVA)
°C
kHz
φ
from
in steps of 30 °
100
per MODULE
Typical loss distribution as a function of
output current
P out=f(T h)
500
3500
Loss distribution
250 Hz
3000
Boost IGBT
static
400
2500
Buck Diode
switch
300
2000
16 kHz
Buck Diode
static
1500
200
Buck IGBT
switch
1000
Buck IGBT
static
100
500
0
0
60
70
Conditions:
80
90
T h ( o C)
79
100
I out (A)
T j= T jmax-25 °C
DC-link=
parameter:
f sw
Conditions:
1200
φ=
0
Switching freq.
from
0
kHz to
158 238 317 396 475 554 634 713 792 871 950 1030 1109 1188
T j=
125
V
f sw=
8
°
DC-link=
φ=
16
1200
0°
°C
kHz
V
kHz
in steps of factor 2
copyright Vincotech
8
08 Dec. 2015 / Revision 1
70-W624N3A1K2SC-L400FP
Application sheet
NPC Application
flow NPC 12w
2400 V / 1200 A
Figure 31.
per MODULE
Typical relativ loss distribution as a function of
output current
P out=f(T h)
1,0
Loss distribution
Boost IGBT
static
0,9
0,8
Buck Diode
switch
0,7
0,6
Buck Diode
static
0,5
0,4
0,3
Buck IGBT
switch
0,2
0,1
11
88
11
09
95
0
10
30
87
1
79
2
71
3
63
4
47
5
55
4
39
6
31
7
23
8
79
0,0
15
8
Buck IGBT
static
I out (A)
Conditions:
T j=
f sw=
DC-link=
φ=
copyright Vincotech
125
8
1200
0°
°C
kHz
V
9
08 Dec. 2015 / Revision 1