10-FZ06BIA041FS01-P898E10 DC Boost Application

10-FZ06BIA041FS01-P898E10
preliminary datasheet
DC Boost Application
flowSOL 0 BI
600V / 41mOhm
General conditions
BOOST
=
=
=
=
VGEon
VGEoff
Rgon
Rgoff
Figure 1.
MOSFET
10 V
0V
8Ω
8Ω
Figure 2.
Typical average static loss as a function of
input current IiRMS
Ploss=f(Iin)
FWD
Typical average static loss as a function of
input current IiRMS
Ploss=f(Iin)
120
Ploss (W)
Ploss (W)
120
Vin/Vout=0,2
100
100
Vin/Vout=1
80
80
60
60
40
40
20
20
Vin/Vout=0,2
Vin/Vout=1
0
0
0
10
20
30
40
Conditions:
Tj=
125
°C
Ratio of input DC voltage to output DC voltage
parameter: Vin/Vout
from
0,2
in
0,2
Figure 3.
to
steps
Iin (A)
0
50
10
20
30
40
Conditions:
Tj=
125
°C
Ratio of input DC voltage to output DC voltage
parameter: Vin/Vout
from
0,2
in
0,2
Figure 4.
1,0
MOSFET
Typical average switching loss as a function of
input current
Ploss=f(Iin)
to
steps
Iin (A)
50
1,0
FWD
Typical average switching loss as a function of
input current
Ploss=f(Iin)
7
Ploss (W)
Ploss (W)
60
6
50
fsw="to" kHz
fsw="to" kHz
5
40
4
30
3
20
2
10
1
fsw="from" kHz
fsw="from" kHz
0
0
0
Conditions:
Sw. freq.
10
20
Tj=
125
Vout =
350
fsw from
16
in steps of factor 2
Copyright by Vincotech
30
40
Iin (A)
50
0
°C
V
Conditions:
kHz to
128
kHz
Sw. freq.
1
10
20
Tj=
125
Vout =
350
fsw from
16
in steps of factor 2
30
40
Iin (A)
50
°C
V
kHz to
128
kHz
Revision: 1
10-FZ06BIA041FS01-P898E10
preliminary datasheet
DC Boost Application
flowSOL 0 BI
Figure 5.
per PHASE
Figure 6.
Typical available input current as a function of
Vin/Vout
Iin=f(Vin/Vout)
per PHASE
Typical available input current as a function of
switching frequency
Iin=f(fsw)
35
Iin (A)
45
Iin (A)
600V / 41mOhm
40
Th=60°C
30
35
Th=60°C
25
30
20
25
Th=100°C
20
15
Th=100°C
15
10
10
5
5
0
0,1
0,2
Conditions:
DC link=
parameter:
0,3
350
0,4
0,5
0,6
Tj= Tjmax-25°C
V
Heatsink temp.
Th from
in
0,7
fsw=
0,8
20
0
0,9
1,0
Vin/Vout
1
10
Conditions:
DC link=
kHz
parameter:
60
10
°C to
°C
100
steps
Figure 7.
°C
per PHASE
Tj= Tjmax-25°C
V
Heatsink temp.
Th from
in
Vin
60
10
°C to
°C
fsw (kHz)
250
V
100
steps
°C
Figure 8.
Typical available input current as a function of
fsw and Vin/Vout
Iin=f(fsw,Vin/Vout)
1000
per PHASE
Typical available electric input power as a function
of heatsink temperature
Pin=f(Th)
0,10
9
Pin (kW)
Iin (A)
350
100
0,20
8
"from" kHz
7
0,30
34,0-36,0
32,0-34,0
6
30,0-32,0
0,40
26,0-28,0
0,50
24,0-26,0
to" kHz
Vin/Vout
28,0-30,0
5
22,0-24,0
4
20,0-22,0
0,60
18,0-20,0
3
16,0-18,0
14,0-16,0
0,70
2
0,80
8
16
32
64
128
1
0,90
256
0
60
65
70
75
80
85
90
fsw (kHz)
Conditions:
Tj= Tjmax-25°C
DC link=
Th=
Copyright by Vincotech
Conditions:
350 V
80 °C
Vin
Sw. freq.
2
95
100
Th ( o C)
Tj= Tjmax-25°C
250 V
fsw from
16
DC link=
kHz to
350 V
128
kHz
Revision: 1
10-FZ06BIA041FS01-P898E10
preliminary datasheet
DC Boost Application
flowSOL 0 BI
Figure 9.
600V / 41mOhm
per PHASE
Typical efficiency as a function of
input power
η=f(Pin)
efficiency (%)
100,00
99,75
99,50
"from" kHz
99,25
99,00
98,75
"to" kHz
98,50
98,25
98,00
0
2
4
6
Conditions:
Tj= Tjmax-25°C
Vin
parameter:
250 V
Sw. freq.
fsw from
Copyright by Vincotech
16
8
10
P in (kW)
DC link=
350 V
kHz to
128 kHz
12
3
Revision: 1
10-FZ06BIA041FS01-P898E10
preliminary datasheet
H bridge application
flowSOL 0 BI
600V / 41mOhm
General conditions
Buck halfwave conduction
VGEon
=
10 V
0V
VGEoff
=
8Ω
Rgon
=
8Ω
Rgoff
=
cosfi = 1
MOSFET
Figure 2.
Figure 1.
FWD
Typical avarage static loss
as a function of output current
Typical avarage static loss
as a function of output current
Ploss=f(Iout)
Ploss=f(Iout)
50
Ploss (W)
Ploss (W)
100
90
Voutpk/Vin=1
45
Voutpk/Vin=0,2
80
40
70
35
60
30
50
25
40
20
30
15
20
10
Voutpk/Vin=0,2
10
5
Voutpk/Vin=1
0
0
0
10
20
30
Conditions:
Tjmax=
Ratio of output peak to input DC voltage
parameter
Voutpk/Vin from
40
50
Iout (A)
0
60
0,2
to
0,2
steps
20
30
Conditions:
Tjmax=
Ratio of output peak to input DC voltage
parameter
Voutpk/Vin from
1,0
MOSFET
0,2
to
0,2
steps
60
1,0
Figure 4.
FWD
Typical avarage switching loss
as a function of output current
Typical avarage switching loss
as a function of output current
Ploss=f(Iout)
Ploss=f(Iout)
18
Ploss (W)
Ploss (W)
50
150 °C
in
Figure 3.
40
Iout (A)
125 °C
in
10
fsw="to"kHz
16
3,5
fsw="to" kHz
3,0
14
2,5
12
2,0
10
8
1,5
6
1,0
4
0,5
2
fsw="from" kHz
fsw="from" kHz
0,0
0
0
10
20
30
40
Conditions:
Tjmax=
DC link=
125 °C
400 V
Switching freq.
parameter
fsw from
in
4
kHz to
* 2 steps
Copyright by Vincotech
50
Iout (A)
0
60
32 kHz
4
10
20
30
40
Conditions:
Tjmax=
DC link=
150 °C
400 V
Switching freq.
parameter
fsw from
in
4
kHz to
* 2 steps
50
Iout (A)
60
32 kHz
Revision: 1
10-FZ06BIA041FS01-P898E10
preliminary datasheet
Figure 5.
per PHASE
Figure 6.
per PHASE
Typical available output current
as a function of Voutpk/Vin
Typical available output current
as a function of switching frequency
Fullwave
Fullwave
Iout=f(Voutpk/Vin)
Iout (A)
Iout(A)
70
Th=60°C
Iout=f(fsw)
60
Th=60°C
60
50
50
40
40
30
Th=100°C
30
Th=100°C
20
20
10
10
0
0
0,1
0,2
Conditions:
fsw=
Heatsink temp.
parameter
0,3
0,4
0,5
Tj=Tjmax
16 kHz
Th from
in
0,6
0,7
0,8
DC link=
60 °C
10 °C
0,9
1,0
Voutpk/Vout
1
Conditions:
Vout
Heatsink temp.
parameter
400 V
to
100 °C
steps
Figure 7.
10
per PHASE
Tj=Tjmax
230 V
Th from
in
fsw (kHz)
DC link=
60 °C
10 °C
to
400 V
100 °C
steps
Figure 8.
per PHASE
Typical available output current
as a function of fsw and Voutpk/Vin
Typical available electric output power as a function
of heatsink temperature
Fullwave
Fullwave
Pout (kW)
Iout=f(fsw,Voutpk/Vin)
0,10
Iout (A)
0,20
100
Pout=f(Th)
14
13
0,30
12
0,40
11
50,0-54,0
46,0-50,0
0,50
42,0-46,0
38,0-42,0
34,0-38,0
Voutpk/Vin
"from" kHz
10
"to" kHz
0,60
9
30,0-34,0
0,70
8
0,80
7
0,90
6
60
1,00
2
Conditions:
4
8
Tj=Tjmax
DC link=
Th=
Copyright by Vincotech
16
32
fsw (kHz)
65
70
75
64
Conditions:
Vout
Switching freq.
parameter
400 V
80 °C
5
Tj=Tjmax
230 V
fsw from
in
80
85
90
95
100
Th ( o C)
DC link=
400 V
4 kHz
to
32 kHz
* 2 steps
Revision: 1
10-FZ06BIA041FS01-P898E10
preliminary datasheet
Figure 9.
per PHASE
Figure 10.
Typical efficiency
as a function of output power
Fullwave
0
efficiency=f(Pout)
efficiency (%)
100,00
efficiency (%)
per PHASE
Typical efficiency
as a function of output power
99,75
efficiency=f(Pout)
99,00
98,75
"from" kHz
98,50
98,25
99,50
"from" kHz
98,00
99,25
"to" kHz
97,75
97,50
99,00
"to" kHz
97,25
98,75
97,00
96,75
98,50
96,50
98,25
96,25
98,00
96,00
0
Conditions:
Vout
Switching freq.
parameter
2
4
6
Tj=Tjmax
230 V
fsw from
in
Copyright by Vincotech
8
10
0
12
14
Pout (kW)
2
4
6
8
10
12
Pout (kW)
Conditions:
Vout
Switching freq.
parameter
DC link=
400 V
4 kHz
to
32 kHz
* 2 steps
6
Tj=Tjmax
110 V
fsw from
in
DC link=
400 V
4 kHz
to
32 kHz
* 2 steps
Revision: 1