10-FZ06NRA099FS-P963F68 NPC Application

10-FZ06NRA099FS-P963F68
preliminary datasheet
NPC Application
flowSOL0-R
600V/18A
General conditions
BUCK
=
=
=
=
VGEon
VGEoff
Rgon
Rgoff
10 V
0V
2Ω
2Ω
Vout= 230 VAC
Figure 1.
Buck MOSFET
BOOST
=
=
=
=
VGEon
VGEoff
Rgon
Rgoff
15 V
-15 V
8Ω
8Ω
Figure 2.
Typical average static loss as a function of
of output current IoRMS
Ploss=f(Iout)
Buck FWD
Typical average static loss as a function of
output current IoRMS
Ploss=f(Iout)
35
Ploss (W)
Ploss (W)
16
φ=0º
φ=90º
14
30
12
25
10
20
8
15
6
φ=0º
10
4
5
2
φ=180º
0
0
0
4
Conditions:
parameter:
8
Tj=
φ
12
125
from
16
I out (A)
0
20
°C
0°
in
12
to
Conditions:
parameter:
180°
4
8
Tj=
φ
12
125
from
steps
Buck MOSFET
0°
12
20
to
180°
steps
Figure 4.
Typical average static loss as a function of
phase displacement φ
Ploss=f(φ)
I out (A)
°C
in
Figure 3.
16
Buck FWD
Typical average static loss as a function of
phase displacement φ
Ploss=f(φ)
35
Ploss (W)
Ploss (W)
16
IoutRMS=Imax
30
IoutRMS=Imax
14
12
25
10
20
8
15
6
10
4
5
2
IoutRMS=6% Imax
IoutRMS=6%Imin
0
0
0
50
Conditions:
parameter:
Tj=
IoRMS
100
125
from
in steps of
copyright by Vincotech
150
φ(º )
200
0
°C
1,33 A
3
to
Conditions:
parameter:
20 A
A
50
Tj=
IoRMS
100
125
from
in steps of
1
150
φ(º )
200
°C
1,33 A
3
to
20 A
A
Revision: 1
10-FZ06NRA099FS-P963F68
preliminary datasheet
NPC Application
flowSOL0-R
Figure 5.
Buck MOSFET
600V/18A
Figure 6.
Buck FWD
Typical average switching loss as a function of
phase displacement φ
Ploss=f(φ)
phase displacement φ
Ploss=f(φ)
0,10
0,8
IoutRMS=Imax
Ploss (W)
Ploss (W)
Typical average switching loss as a function of
0,7
IoutRMS=Imax
0,08
0,6
0,5
0,06
0,4
0,04
0,3
IoutRMS=6% Imax
0,2
IoutRMS=6% Imax
0,02
0,1
0,0
0,00
50
Conditions:
parameter:
100
Tj=
fsw=
125
20
°C
kHz
DC link=
IoRMS
700
from
V
150
0
50
Conditions:
1,33 A
in steps of
200
φ(º )
3
to
20 A
parameter:
Tj=
fsw=
125
20
°C
kHz
DC link=
IoRMS
700
from
V
A
Figure 7.
100
1,33 A
in steps of
Buck MOSFET
150
3
to
20 A
A
Figure 8.
Typical total loss as a function of
phase displacement φ and output current IoRMS
Ploss=f(IoRMS;φ)
Buck FWD
Typical total loss as a function of
phase displacement φ and output current IoRMS
Ploss=f(IoRMS;φ)
20
20
P loss (W)
32-36
17
P loss (W)
17
12-15
16
28-32
19
IoutRMS
19
16
15
15
24-28
13
13
9-12
12
12
20-24
11
11
6-9
16-20
9
9
8
8
12-16
3-6
7
8-12
7
5
5
4
4-8
4
0-3
3
0-4
0
15
30
45
60
75
90
3
1
105 120 135 150 165 180
0
15
30
45
60
75
90
Tj=
125
°C
DC link=
fsw=
700
20
V
kHz
copyright by Vincotech
1
105 120 135 150 165 180
φ(º )
φ(º )
Conditions:
200
φ(º )
IoutRMS
0
Conditions:
2
Tj=
125
°C
DC link=
fsw=
700
20
V
kHz
Revision: 1
10-FZ06NRA099FS-P963F68
preliminary datasheet
NPC Application
flowSOL0-R
Figure 9.
for Buck MOSFET+FWD
600V/18A
Figure 10.
for Buck MOSFET+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)
30
Iout (A)
Iout (A)
30
Th=50°C
Th=50°C
25
25
20
20
Th=100°C
15
15
Th=100°C
10
10
5
5
0
0
Conditions:
20
40
60
80
100
120
Tj= Tjmax-25 °C
140
160
fsw=
1
20 kHz
Conditions:
DC link=
parameter:
700
V
Heatsink temp.
Th from
50
°C to
in
10
°C
0
180
φ
parameter:
100
steps
Figure 11.
°C
10
100
fsw (kHz)
φ= 0 °
Tj= Tjmax-25 °C
DC link=
Heatsink temp.
Th from
in
700
50
10
1000
V
°C to
°C
100
steps
°C
for Buck IGBT+FWD
Typical available 50Hz output current as a function of
fsw and phase displacement φ
Iout=f(fsw,φ)
180
I out (A)
φ
165
150
135
24-25
120
23-24
105
90
22-23
75
60
21-22
45
20-21
30
15
2
4
8
16
32
64
0
128
fsw (kHz)
Conditions:
Tj= Tjmax-25 °C
DC link=
Th=
copyright by Vincotech
700
80
V
°C
3
Revision: 1
10-FZ06NRA099FS-P963F68
preliminary datasheet
flowSOL0-R
NPC Application
Figure 12.
Boost IGBT
600V/18A
Figure 13.
Typical average static loss as a function of
output current
Ploss=f(Iout)
Boost FWD
Typical average static loss as a function of
output current
Ploss=f(Iout)
16
Ploss (W)
Ploss (W)
12
φ=180º
10
φ=0º
12
8
8
6
4
4
2
φ=180º
φ=0º
0
0
0
4
Conditions:
parameter:
8
Tj=
125
φ
from
in
12
16
I out (A)
0
20
°C
5
Conditions:
0°
12
to
steps
Figure 14.
180º
parameter:
Boost IGBT
10
Tj=
125
φ
from
in
I out (A)
20
°C
0°
12
to
steps
Figure 15.
Typical average static loss
as a function of phase displacement
Ploss=f(φ)
180º
Boost FWD
Typical average static loss
as a function of phase displacement
Ploss=f(φ)
FWD D1
16
Ploss (W)
12
Ploss (W)
15
IoutRMS=Imax
IoutRMS=Imax
14
10
12
8
10
6
8
6
4
4
2
2
IoutRMS=6% Imax
IoutRMS=6% Imax
0
0
0
Conditions:
parameter:
50
Tj=
IoRMS
100
125
from
in steps of
copyright by Vincotech
150
φ(º )
200
0
°C
1 A
to
Conditions:
parameter:
20 A
3 A
50
Tj=
IoRMS
100
125
from
in steps of
4
150
φ(º )
200
°C
1 A
to
20 A
3 A
Revision: 1
10-FZ06NRA099FS-P963F68
preliminary datasheet
flowSOL0-R
NPC Application
Figure 16.
Boost IGBT
600V/18A
Figure 17.
Typical average switching loss as a function of
phase displacement
Ploss=f(φ)
Boost FWD
Typical average switching loss as a function of
phase displacement
Ploss=f(φ)
10
Ploss (W)
Ploss (W)
16
IoutRMS=Imax
IoutRMS=Imax
8
12
6
8
4
4
2
IoutRMS=6% Imax
IoutRMS=6% Imax
0
0
0
50
Conditions:
150
fsw=
Tj=
125
°C
DC link=
IoRMS
700
from
V
in steps of
1 A
to
3 A
A
φ(º )
0
200
20 kHz
50
Conditions:
20 A
parameter:
100
150
fsw=
20 kHz
1 A
to
20 A
3 A
A
Tj=
125
°C
DC link=
IoRMS
700
from
V
in steps of
Figure 18.
Boost IGBT
Figure 19.
Typical total loss as a function of phase displacement
and IoutRMS
200
φ(º )
Boost FWD
Typical total loss as a function of phase displacement
and IoutRMS
Ploss=f(IoRMS;φ)
Ploss=f(IoRMS;φ)
20
P loss (W)
17
16-18
16
20
IoutRMS
19
19
P loss (W)
17
IoutRMS
parameter:
100
16
20-25
15
15
14-16
13
13
15-20
12-14
12
12
10-12
11
11
10-15
9
9
8-10
8
8
6-8
7
5-10
7
4-6
5
5
4
2-4
4
0-2
0-5
3
3
0
15
30
45
60
75
90
1
105 120 135 150 165 180
0
15
30
45
60
75
90
1
105 120 135 150 165 180
φ(º )
φ(º )
Conditions:
Tj=
125
°C
DC link=
fsw=
700
20
V
kHz
copyright by Vincotech
Conditions:
5
Tj=
125
°C
DC link=
fsw=
700
20
V
kHz
Revision: 1
10-FZ06NRA099FS-P963F68
preliminary datasheet
NPC Application
flowSOL0-R
Figure 20.
Boost IGBT+FWD
600V/18A
Figure 21.
Typical available output current as a function of
of phase displacement
Iout=f(φ)
Boost IGBT+FWD
Typical available output current
as a function of switching frequency
Iout=f(fsw)
60
Iout (A)
Iout (A)
60
Th=50°C
50
Th=50°C
50
Th=100°C
40
40
30
30
20
20
10
Th=100°C
10
0
0
20
Conditions:
40
60
80
100
120
140
Tj= Tjmax-25 °C
DC link=
700
V
parameter:
Th from
in
160
fsw=
Heatsink temp.
50
°C to
10
°C
φ(º )
0
180
20 kHz
1
10
Conditions:
Tj= Tjmax-25 °C
DC link=
700
V
parameter:
100
steps
Figure 22.
°C
Th from
in
Heatsink temp.
50
°C to
10
°C
f sw (kHz)
100
1000
φ= 90°
100
steps
°C
Boost IGBT+FWD
Typical available 50Hz output current as a function of
fsw and phase displacement
Iout=f(fsw,φ)
180
φ
165
I out (A)
150
135
0-10
10-20
120
105
90
20-30
75
30-40
60
45
30
40-50
50-60
15
2
4
8
16
32
64
0
128
fsw (kHz)
Conditions:
Tj= Tjmax-25 °C
DC link=
Th=
copyright by Vincotech
700
80
V
°C
6
Revision: 1
10-FZ06NRA099FS-P963F68
preliminary datasheet
NPC Application
flowSOL0-R
Figure 23.
per MODULE
600V/18A
Figure 24.
Typical available output current as a function of
heat sink temperature
Iout=f(Th)
per MODULE
Typical available output current
as a function of phase displacement
Iout=f(φ)
30
Iout (A)
Iout (A)
30
Th=50°C
25
25
2kHz
20
20
128kHz
Th=100°C
15
15
10
10
5
5
0
0
60
65
70
Conditions:
75
80
85
90
95
T h ( o C)
0
100
Tj= Tjmax-25 °C
DC link=
φ=
parameter:
40
Conditions:
700
V
0°
Switching freq.
fsw from
2
in steps of factor 2
20
parameter:
128
Figure 25.
kHz
100
120
140
50
10
°C to
°C
180
per MODULE
Typical available 50Hz output current as a function of
fsw and phase displacement
Iout=f(fsw,φ)
180
30
Iout (A)
φ
100
steps
Figure 26.
Typical available output current as a function of
switching frequency
Iout=f(fsw)
160
700
V
20
kHz
Heatsink temp.
Th from
in
per MODULE
80
Tj= Tjmax-25 °C
DC link=
fsw=
kHz to
60
φ
165
I out (A)
Th=50°C
150
25
20-25
135
120
20
15-20
105
90
10-15
15
Th=100°C
75
5-10
60
10
45
0-5
30
5
15
0
2
1
10
Conditions:
Tj= Tjmax-25 °C
DC link=
parameter:
Th from
in
100
50
10
copyright by Vincotech
φ=
f sw (kHz)
8
16
32
64
0
128
f sw (kHz)
0°
Conditions:
700
V
Heatsink temp.
°C to
°C
4
1000
Tj= Tjmax-25 °C
DC link=
Th=
700
80
V
°C
100
steps
7
Revision: 1
10-FZ06NRA099FS-P963F68
preliminary datasheet
NPC Application
flowSOL0-R
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)
efficiency (%)
100
efficiency (%)
600V/18A
φ=0º
99
100,0
99,5
2kHz
99,0
98
φ=180º
98,5
97
128kHz
96
98,0
95
97,5
97,0
94
0
1
2
3
4
0
5
1
2
3
4
5
P out (kVA)
Conditions:
Tj=
fsw=
125
20
P out (kVA)
°C
kHz
Conditions:
DC link=
parameter:
700
V
phase displacement
φ
from
0°
in steps of 30 °
Tj=
DC link=
parameter:
to
Figure 29.
φ= 0 °
°C
V
Switching freq.
fsw from
2
kHz to
in steps of factor 2
180 °
per MODULE
125
700
128
kHz
Figure 30.
per MODULE
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)
7
Pout (kW)
60,0
Loss distribution
6
50,0
2kHz
T1 Stat.
5
D3-5
Sw.
128kHz
40,0
4
D3-5
Stat.
30,0
T3 Sw.
3
T3 Stat.
20,0
2
10,0
1
0,0
0
60
Conditions:
parameter:
65
70
75
80
85
Tj= Tjmax-25 °C
DC link=
700
φ=
0
Switching freq.
fsw from
2
kHz to
in steps of factor 2
copyright by Vincotech
90
1
95
100
T h ( o C)
4
5
7
8
9
11
12
13
15
16
17
19
20
Iout (A)
Conditions:
V
°
128
3
Tj=
fsw=
125
20
°C
kHz
DC link=
φ=
700
0°
V
kHz
8
Revision: 1
10-FZ06NRA099FS-P963F68
preliminary datasheet
NPC Application
flowSOL0-R
Figure 31.
Typical relativ loss distribution as a function of
output current
Pout=f(Th)
per MODULE
Figure 32.
600V/18A
Typical Application
1,0
Loss distribution
0,8
0,6
T1 Stat.
D3-5
Sw.
0,4
D3-5
Stat.
T3 Sw.
0,2
T3 Stat.
0,0
1
Conditions:
3
4
Tj=
fsw=
DC link=
φ=
copyright by Vincotech
5
7
125
20
700
0°
8
9
11
12
13
15
16
17
19
20
Iout (A)
°C
kHz
V
9
Revision: 1