30-FT12NMA200SH-M660F08

30-FT12NMA200SH-M660F08
mixed voltage NPC Application
flow2 MNPC
1200V/200A
General conditions
VGEon
VGEoff
Rgon
Rgoff
half bridge IGBT
=
=
=
=
15 V
-15 V
2Ω
neutral point IGBT
VGEon
=
15 V
VGEoff
=
-15 V
2Ω
Rgon
=
Rgoff
2Ω
=
Vout= 230 VAC
2Ω
half bridge IGBT
Figure 1.
Figure 2.
Typical average static loss as a function of
of output current IoRMS
Ploss=f(Iout)
neutral point FWD
Typical average static loss as a function of
output current IoRMS
Ploss=f(Iout)
70
Ploss (W)
Ploss (W)
140
φ=90º
60
120
φ=0º
100
50
80
40
60
30
40
20
φ=0º
10
20
φ
φ=180º
0
0
0
40
80
120
0
160
40
80
120
I out (A)
Conditions:
parameter:
Tj=
φ
150
from
°C
0°
in
12
to
Conditions:
parameter:
180°
Tj=
φ
125
from
steps
°C
0°
in
half bridge IGBT
Figure 3.
160
I out (A)
12
to
Figure 4.
Typical average static loss as a function of
phase displacement φ
Ploss=f(φ)
180°
steps
neutral point FWD
Typical average static loss as a function of
phase displacement φ
Ploss=f(φ)
Ploss (W)
70
Ploss (W)
140
IoutRMS=Imax
IoutRMS=Imax
120
60
100
50
80
40
60
30
40
20
10
20
IoutRMS=6% Imax
IoutRMS=6%Imax
0
0
0
Conditions:
parameter:
50
Tj=
IoRMS
100
150
from
in steps of
copyright by Vincotech
150
φ(º )
200
°C
10 A
20
to
150 A
A
0
50
Conditions:
parameter:
Tj=
IoRMS
100
125
from
in steps of
1
150
φ(º )
200
°C
10 A
20
to
150 A
A
Revision: 1
30-FT12NMA200SH-M660F08
mixed voltage NPC Application
flow2 MNPC
Figure 5.
half bridge IGBT
1200V/200A
Figure 6.
neutral point FWD
Typical average switching loss as a function of
Typical average switching loss as a function of
phase displacement φ
Ploss=f(φ)
phase displacement φ
Ploss=f(φ)
70
Ploss (W)
Ploss (W)
15
IoutRMS=Imax
IoutRMS=Imax
60
12
50
9
40
30
6
20
3
IoutRMS=6% Imax
10
IoutRMS=6% Imax
0
0
50
φ(º )
150
Tj=
fsw=
150
16
°C
kHz
DC link=
IoRMS
700
from
V
Conditions:
parameter:
100
10 A
in steps of
20
to
200
150 A
50
Conditions:
Tj=
fsw=
125
16
°C
kHz
DC link=
IoRMS
700
from
V
parameter:
100
A
Figure 7.
150
0
10 A
in steps of
half bridge IGBT
20
to
200
150 A
A
Figure 8.
Typical total loss as a function of
phase displacement φ and output current IoRMS
Ploss=f(IoRMS;φ)
φ(º )
neutral point FWD
Typical total loss as a function of
phase displacement φ and output current IoRMS
Ploss=f(IoRMS;φ)
150
150
P loss (W)
130
175-200
IoutRMS
140
P loss (W)
140
130
60-75
120
120
150-175
IoutRMS
0
110
110
45-60
100
100
125-150
90
90
100-125
80
80
30-45
70
70
75-100
60
60
50-75
50
15-30
50
40
40
25-50
30
30
0-15
0-25
20
20
0
15
30
45
60
75
90
10
105 120 135 150 165 180
0
15
30
45
60
75
90
φ(º )
φ(º )
Conditions:
Tj=
150
°C
DC link=
fsw=
700
16
V
kHz
copyright by Vincotech
10
105 120 135 150 165 180
Conditions:
2
Tj=
125
°C
DC link=
fsw=
700
16
V
kHz
Revision: 1
30-FT12NMA200SH-M660F08
mixed voltage NPC Application
flow2 MNPC
Figure 9.
for half bridge IGBT + neutral point FWD
Figure 10.
1200V/200A
for half bridge IGBT + neutral point FWD
Typical available output current as a function of
phase displacement φ
Typical available output current as a function of
switching frequency fsw
Iout=f(φ)
Iout=f(fsw)
Iout (A)
300
Iout (A)
300
Th=50°C
Th=50°C
250
250
200
200
150
150
Th=100°C
100
100
Th=100°C
50
50
0
0
30
Conditions:
60
Tj=
90
150/125
120
150
°C
fsw=
1
16 kHz
Conditions:
DC link=
parameter:
700
V
Heatsink temp.
Th from
50
°C to
in
10
°C
0
180
φ(º )
Figure 11.
parameter:
100
steps
°C
10
Tj=
DC link=
Heatsink temp.
Th from
in
150/125
°C
700
V
50
10
fsw (kHz)
100
φ= 0 °
°C to
°C
100
steps
°C
for half bridge IGBT + neutral point FWD
Typical available 50Hz output current as a function of
fsw and phase displacement φ
Iout=f(fsw,φ)
180
165
φ(º )
I out (A)
150
270-300
135
240-270
120
210-240
105
180-210
90
150-180
75
120-150
60
90-120
45
60-90
30
30-60
15
2
4
8
16
32
64
0
128
fsw (kHz)
Conditions:
Tj=
DC link=
Th=
copyright by Vincotech
150/125
°C
700
80
V
°C
3
Revision: 1
30-FT12NMA200SH-M660F08
mixed voltage NPC Application
flow2 MNPC
Figure 12.
neutral point IGBT
1200V/200A
Figure 13.
Typical average static loss as a function of
output current
Ploss=f(Iout)
half bridge FWD
Typical average static loss as a function of
output current
Ploss=f(Iout)
70
Ploss (W)
Ploss (W)
175
φ=0º
φ=180º
60
150
50
125
40
100
30
75
φ=180º
20
50
10
25
φ=0º
0
0
0
Conditions:
parameter:
40
80
Tj=
150
φ
from
in
120
Iout (A)
160
0
°C
Conditions:
0°
12
Figure 14.
to
steps
180º
parameter:
neutral point IGBT
40
80
Tj=
150
φ
from
in
Iout (A)
160
°C
0°
12
Figure 15.
Typical average static loss
as a function of phase displacement
Ploss=f(φ)
to
steps
180º
half bridge FWD
Typical average static loss
as a function of phase displacement
Ploss=f(φ)
70
FWD D1
175
Ploss (W)
120
Ploss (W)
IoutRMS=Imax
IoutRMS=Imax
60
150
50
125
40
100
30
75
50
20
25
10
IoutRMS=6% Imax
IoutRMS=6% Imax
0
0
0
Conditions:
parameter:
50
Tj=
IoRMS
100
150
from
in steps of
copyright by Vincotech
150
φ(º )
0
200
°C
10 A
to
Conditions:
parameter:
150 A
20 A
50
Tj=
IoRMS
100
125
from
in steps of
4
150
φ(º )
200
°C
10 A
to
150 A
20 A
Revision: 1
30-FT12NMA200SH-M660F08
mixed voltage NPC Application
flow2 MNPC
Figure 16.
neutral point IGBT
1200V/200A
Figure 17.
Typical average switching loss as a function of
phase displacement
Ploss=f(φ)
half bridge FWD
Typical average switching loss as a function of
phase displacement
Ploss=f(φ)
30
Ploss (W)
Ploss (W)
50
IoutRMS=Imax
IoutRMS=Imax
25
40
20
30
15
20
10
IoutRMS=6% Imax
10
5
IoutRMS=6% Imax
0
0
0
50
150
fsw=
Tj=
150
°C
DC link=
IoRMS
700
from
V
Conditions:
in steps of
10 A
to
20 A
A
Figure 18.
φ(º )
0
200
16 kHz
50
Conditions:
150 A
parameter:
150
fsw=
16 kHz
10 A
to
150 A
20 A
A
Tj=
125
°C
DC link=
IoRMS
700
from
V
in steps of
neutral point IGBT
100
Figure 19.
Typical total loss as a function of phase displacement
and IoutRMS
φ(º )
200
half bridge FWD
Typical total loss as a function of phase displacement
and IoutRMS
Ploss=f(IoRMS;φ)
Ploss=f(IoRMS;φ)
150
150
140
P loss (W)
130
90-100
IoutRMS
140
P loss (W)
130
120
180-200
80-90
110
160-180
110
70-80
100
140-160
100
60-70
90
120-140
90
50-60
80
40-50
70
30-40
60
20-30
50
120
IoutRMS
parameter:
100
80
100-120
70
80-100
60
60-80
50
40-60
40
40
10-20
20-40
30
30
0-10
0-20
20
0
15
30
45
60
75
90
10
105 120 135 150 165 180
20
0
15
30
45
60
75
90
10
105 120 135 150 165 180
φ(º )
Conditions:
Tj=
150
°C
DC link=
fsw=
700
16
V
kHz
copyright by Vincotech
φ(º )
Conditions:
5
Tj=
125
°C
DC link=
fsw=
700
16
V
kHz
Revision: 1
30-FT12NMA200SH-M660F08
mixed voltage NPC Application
flow2 MNPC
Figure 20.
for neutral point IGBT + half bridge FWD
1200V/200A
Figure 21.
Typical available output current as a function of
of phase displacement
Iout=f(φ)
for neutral point IGBT + half bridge FWD
Typical available output current
as a function of switching frequency
Iout=f(fsw)
300
Iout (A)
Iout (A)
300
250
250
Th=50°C
Th=50°C
200
200
150
150
Th=100°C
Th=100°C
100
100
50
50
0
0
0
30
60
90
120
150
180
1
φ(º )
Tj=
DC link=
Conditions:
parameter:
Th from
in
150/125
700
°C
V
fsw=
Heatsink temp.
50
°C to
10
°C
Figure 22.
16 kHz
Conditions:
10
Tj=
DC link=
parameter:
100
steps
°C
Th from
in
150/125
700
100
f sw (kHz)
°C
V
Heatsink temp.
50
°C to
10
°C
1000
φ= 90°
100
steps
°C
for neutral point IGBT + half bridge FWD
Typical available 50Hz output current as a function of
fsw and phase displacement
Iout=f(fsw,φ)
180
165
I out (A)
φ(º )
150
240-260
220-240
135
200-220
120
180-200
105
160-180
90
140-160
75
120-140
60
100-120
45
80-100
60-80
30
40-60
15
2
4
8
16
32
64
f sw
Conditions:
Tj=
DC link=
Th=
copyright by Vincotech
150/125
°C
700
80
V
°C
0
128
(kHz)
6
Revision: 1
30-FT12NMA200SH-M660F08
mixed voltage NPC Application
flow2 MNPC
Figure 23.
per PHASE
1200V/200A
Figure 24.
Typical available output current as a function of
heat sink temperature
Iout=f(Th)
per PHASE
Typical available output current
as a function of phase displacement
Iout=f(φ)
250
Th=50°C
Iout (A)
Iout (A)
250
2kHz
200
200
150
150
100
100
Th=100°C
50
50
128kHz
0
0
60
70
Tj=
Conditions:
DC link=
φ=
parameter:
80
150/125
90
T h ( o C)
0
100
60
°C
Conditions:
Tj=
DC link=
fsw=
parameter:
kHz to
128
Figure 25.
90
120
150
180
φ(º )
700
V
0°
Switching freq.
fsw from
2
in steps of factor 2
30
kHz
150/125
Th from
in
per PHASE
°C
700
V
16
kHz
Heatsink temp.
50
10
°C to
°C
100
steps
Figure 26.
Typical available output current as a function of
switching frequency
Iout=f(fsw)
per PHASE
Typical available 50Hz output current as a function of
fsw and phase displacement
Iout=f(fsw,φ)
180
300
Iout (A)
φ(º )
165
I out (A)
Th=50°C
150
250
225-250
135
200-225
120
200
175-200
105
150-175
90
150
125-150
75
100-125
Th=100°C
60
75-100
100
45
50-75
30
25-50
50
15
0-25
0
2
1
Conditions:
Tj=
DC link=
parameter:
Th from
in
f sw (kHz)
10
50
10
copyright by Vincotech
150/125
°C
φ=
8
16
32
64
0
128
fsw (kHz)
0°
Conditions:
700
V
Heatsink temp.
°C to
°C
4
100
Tj=
DC link=
Th=
150/125
°C
700
80
V
°C
100
steps
7
Revision: 1
30-FT12NMA200SH-M660F08
mixed voltage NPC Application
flow2 MNPC
Figure 27.
per PHASE
Figure 28.
Typical efficiency as a function of output power
η=f(Pout)
per PHASE
Typical efficiency as a function of output power
η=f(Pout)
100
efficiency (%)
100,0
efficiency (%)
1200V/200A
2kHz
99,5
99
99,0
98
φ=0º
97
98,5
φ=180º
98,0
96
97,5
95
128kHz
0
Conditions:
5
10
Tj=
fsw=
15
150/125
16
20
25
30
35
Pout (kVA)
0
°C
kHz
Conditions:
700
V
phase displacement
φ
from
0°
in steps of 30 °
parameter:
to
Figure 29.
10
15
20
25
30
35
Pout (kVA)
DC link=
parameter:
5
180 °
per PHASE
Tj=
DC link=
150/125
700
°C
V
φ= 0 °
Switching freq.
fsw from
2
kHz to
in steps of factor 2
128
kHz
Figure 30.
per PHASE
Typical available output power as a function of
Typical loss distribution as a function of
heat sink temperature
Pout=f(Th)
output current
Pout=f(Th)
160
Pout (kVA)
60
Loss distribution
2kHz
140
50
120
NP.IGBT.Stat.
40
100
NP.FWD.Sw.
80
30
NP FWD.Stat.
HB.IGBT.Sw.
60
20
HB.IGBT.Stat.
40
128kHz
10
20
0
0
60
70
80
90
o
10
100
20
30
40
50
60
70
T h ( C)
Conditions:
parameter:
Tj=
150/125 °C
DC link=
700
φ=
0°
Switching freq.
fsw from
2
kHz to
in steps of factor 2
copyright by Vincotech
90
100
110
120
130
140
150
Iout (A)
Conditions:
V
Tj=
fsw=
DC link=
φ=
128
80
150/125
16
700
0°
°C
kHz
V
kHz
8
Revision: 1
30-FT12NMA200SH-M660F08
mixed voltage NPC Application
flow2 MNPC
Figure 31.
Typical relativ loss distribution as a function of
output current
Pout=f(Th)
per PHASE
1200V/200A
Figure 32.
Schematic
1,0
Loss distribution
NP.IGBT.Stat.
0,8
NP.FWD.Sw.
0,6
NP FWD.Stat.
0,4
HB.IGBT.Sw.
0,2
HB.IGBT.Stat.
0,0
10
20
30
40
50
60
70
80
90
100 110 120 130 140 150
Iout (A)
Conditions:
Tj=
fsw=
DC link=
φ=
copyright by Vincotech
150/125
16
700
0°
°C
kHz
V
9
Revision: 1