ABB 5SGF40L4502

VDRM
ITGQM
ITSM
VT0
rT
VDclink
=
=
=
=
=
=
4500
4000
25×103
1.2
0.65
2800
V
A
A
V
mΩ
Ω
V
Asymmetric Gate turn-off
Thyristor
5SGF 40L4502
Doc. No. 5SYA1209-04 Jan. 03
• Patented free-floating silicon technology
• Low on-state and switching losses
• Annular gate electrode
• Industry standard housing
• Cosmic radiation withstand rating
Blocking
Maximum rated values
1)
Parameter
Symbol Conditions
Repetitive peak off-state
voltage
VDRM
Repetitive peak reverse
voltage
VRRM
Permanent DC voltage for
100 FIT failure rate
VDclink
min
typ
VGR ≥ 2 V
Ambient cosmic radiation at sea level
in open air.
max
Unit
4500
V
17
V
2800
V
max
Unit
Characteristic values
Parameter
Symbol Conditions
min
typ
Repetitive peak off-state
current
IDRM
VD = VDRM, VGR ≥ 2 V
100
mA
Repetitive peak reverse
current
IRRM
VR = VRRM, RGK = ∞ Ω
50
mA
Mechanical data
Maximum rated values
1)
Parameter
Symbol Conditions
Mounting force
Fm
min
typ
max
Unit
36
40
44
kN
min
typ
max
Unit
Characteristic values
Parameter
Symbol Conditions
Pole-piece diameter
Dp
± 0.1 mm
75
mm
Housing thickness
H
± 0.5 mm
26
mm
Weight
m
1.5
kg
Surface creepage distance
Ds
Anode to Gate
33
Air strike distance
Da
Anode to Gate
14
1) Maximum rated values indicate limits beyond which damage to the device may occur
ABB Switzerland Ltd, Semiconductors reserves the right to change specifications without notice.
mm
mm
5SGF 40L4502
GTO Data
On-state
Maximum rated values
1)
Parameter
Symbol Conditions
Max. average on-state
current
ITAVM
min
typ
Half sine wave, TC = 85 °C
Max. RMS on-state current ITRMS
Max. peak non-repetitive
surge current
ITSM
Limiting load integral
I2t
Max. peak non-repetitive
surge current
ITSM
Limiting load integral
I2t
max
Unit
1180
A
1850
tp = 10 ms, Tvj = 125°C, sine wave
After Surge: VD = VR = 0 V
A
3
A
6
A2s
3
A
25×10
3.1×10
tp = 1 ms, Tvj = 125°C, sine wave
After Surge: VD = VR = 0 V
40×10
3
800×10
A2s
max
Unit
Characteristic values
Parameter
Symbol Conditions
min
typ
On-state voltage
VT
IT = 4000 A, Tvj = 125°C
3.8
V
Threshold voltage
V(T0)
1.2
V
Slope resistance
rT
Tvj = 125°C
IT = 400...5000 A
0.65
mΩ
Holding current
IH
Tvj = 25°C
100
A
max
Unit
500
A/µs
1000
A/µs
Turn-on switching
Maximum rated values
1)
Parameter
Symbol Conditions
Critical rate of rise of onstate current
diT/dtcr
Critical rate of rise of onstate current
diT/dtcr
Min. on-time
ton
100
Parameter
Symbol Conditions
min
Turn-on delay time
td
Rise time
tr
Turn-on energy per pulse
Eon
Tvj = 125°C,
IT = 4000 A, IGM = 50 A,
diG/dt = 40 A/µs
min
typ
f = 200 Hz
f = 1 Hz
µs
Characteristic values
typ
VD = 0.5 VDRM, Tvj = 125 °C
IT = 4000 A, di/dt = 300 A/µs,
IGM = 50 A, diG/dt = 40 A/µs, CS = 6
µF, RS = 5 Ω
max
Unit
2.5
µs
5
µs
3
J
max
Unit
4000
A
Turn-off switching
Maximum rated values
1)
Parameter
Max. controllable turn-off
current
Min. off-time
Symbol Conditions
ITGQM
min
typ
VDM ≤ VDRM, diGQ/dt = 40 A/µs,
CS = 6 µF, LS ≤ 0.2 µH
toff
100
µs
Characteristic values
Parameter
Symbol Conditions
Storage time
tS
Fall time
tf
Turn-on energy per pulse
Eoff
Peak turn-off gate current
IGQM
min
typ
VD = 0.5 VDRM, Tvj = 125 °C
VDM ≤ VDRM, diGQ/dt = 40 A/µs,
ITGQ = ITGQM,
RS = 5Ω, CS = 6 µF, LS = 0.2 µH
max
Unit
25
µs
3
µs
10
J
1100
A
ABB Switzerland Ltd, Semiconductors reserves the right to change specifications without notice.
Doc. No. 5SYA1209-04 Jan. 03
page 2 of 9
5SGF 40L4502
Gate
Maximum rated values
1)
Parameter
Symbol Conditions
Repetetive peak reverse
voltage
VGRM
Repetetive peak reverse
current
IGRM
min
typ
max
Unit
17
V
20
mA
max
Unit
VGR = VGRM
Characteristic values
Parameter
Symbol Conditions
Gate trigger voltage
VGT
Gate trigger current
IGT
Thermal
Maximum rated values
min
Tvj = 25°C,
VD = 24 V, RA = 0.1 Ω
typ
1.2
V
4
A
1)
Parameter
Symbol
Conditions
min
typ
max
Unit
Junction operating temperature
Tvj
-40
125
°C
Storage temperature range
Tstg
-40
125
°C
max
Unit
Characteristic values
Parameter
Symbol
Thermal resistance junction to case
Thermal resistance case to heatsink
(Double side cooled)
Conditions
min
typ
Rth(jc)
Double side cooled
11
K/kW
Rth(jc)A
Anode side cooled
20
K/kW
Rth(jc)C
Cathode side cooled
25
K/kW
Rth(ch)
Single side cooled
6
K/kW
Rth(ch)
Double side cooled
3
K/kW
Analytical function for transient thermal
impedance:
n
ZthJC(t) = å Ri(1 - e -t/τ i )
i =1
i
1
2
3
4
Ri(K/kW)
7.766
1.728
1.064
0.450
τi(s)
0.5764
0.1258
0.0128
0.0031
Fig. 1 Transient thermal impedance, junction to
case.
ABB Switzerland Ltd, Semiconductors reserves the right to change specifications without notice.
Doc. No. 5SYA1209-04 Jan. 03
page 3 of 9
5SGF 40L4502
Fig. 2 On-state characteristics.
Fig. 3 Average on-state power dissipation vs.
average on-state current.
Fig. 4 Surge current and fusing integral vs. pulse
width.
ABB Switzerland Ltd, Semiconductors reserves the right to change specifications without notice.
Doc. No. 5SYA1209-04 Jan. 03
page 4 of 9
5SGF 40L4502
Fig. 5 Forward blocking voltage vs. gate-cathode
resistance.
Fig. 6 Static dv/dt capability: Forward blocking
voltage vs. neg. gate voltage or gate cathode
resistance.
Fig. 7 Forward gate current vs. forard gate voltage.
Fig. 8 Gate trigger current vs. junction temperature
ABB Switzerland Ltd, Semiconductors reserves the right to change specifications without notice.
Doc. No. 5SYA1209-04 Jan. 03
page 5 of 9
5SGF 40L4502
Fig. 9 Turn-on energy per pulse vs. on-state current
and turn-on voltage.
Fig. 10 Turn-on energy per pulse vs. on.-state current
and current rise rate
Common Test conditions for figures 9, 10 and 11:
diG/dt
= 40 A/µs
CS
= 6 µF
RS
=5Ω
Tj
= 125 °C
Definition of Turn-on energy:
20 µ s
E on =
òV
D
⋅ ITdt
(t = 0, IG = 0.1 ⋅ IGM )
0
Common Test conditions for figures 12, 13 and 15:
Definition of Turn-off energy:
40 µ s
E off =
òV
D
⋅ ITdt
( t = 0, IT = 0.9 ⋅ ITGQ )
0
Fig. 11 Turn-on energy per pulse vs. on-state current
and turn-on voltage.
ABB Switzerland Ltd, Semiconductors reserves the right to change specifications without notice.
Doc. No. 5SYA1209-04 Jan. 03
page 6 of 9
5SGF 40L4502
Fig. 12 Turn-off energy per pulse vs. turn-off current
and peak turn-off voltage. Extracted gate
charge vs. turn-off current.
Fig. 13 Turn-off energy per pulse vs. turn-off current
and snubber capacitance.
Fig. 14 Required snubber capacitor vs. max
allowable turn-off current.
Fig. 15 Turn-off energy per pulse, storage time and
peak turn-off gate current vs. junction
temperature.
IGQM [A]
ts [s]
50
1200
IGQM [A]
ts [s]
1200
60
Preliminary Data
45
IGQM
40
1100
35
Preliminary Data
30
50
1000
40
800
1000
25
tS
IGQM
30
600
20
400
900
20
15
Conditions:
ITGQ = 4000 A
T j = 125 °C
10
5
800
700
0
0
10
20
30
40
50
60
tS
10
Conditions:
µs
diGQ /dt =40 A/µ
T j = 125 °C
0
0
500
1000
1500
2000
2500
µ s]
diGQ /dt [A/µ
Fig. 16 Storage time and peak turn-off gate current
vs. neg. gate current rise rate.
3000
3500
200
0
4000
ITGQ [A]
Fig. 17 Storage time and peak turn-off gate current
vs. turn-off current.
ABB Switzerland Ltd, Semiconductors reserves the right to change specifications without notice.
Doc. No. 5SYA1209-04 Jan. 03
page 7 of 9
5SGF 40L4502
Fig. 18 General current and voltage waveforms with GTO-specific symbols.
Fig. 19 Outline drawing. All dimensions are in millimeters and represent nominal values unless stated otherwise.
ABB Switzerland Ltd, Semiconductors reserves the right to change specifications without notice.
Doc. No. 5SYA1209-04 Jan. 03
page 8 of 9
5SGF 40L4502
The 5SGF 40L4502 is a 91 mm buffered layer GTO with exceptionally low dynamic and static losses designed to
retro-fit all former 4 kA GTOs of the same voltage. It offers optimal trade-off between on-state and switching
losses and is encapsulated in an industry-standard press pack housing 120 mm wide and 26 mm thick.
ABB Switzerland Ltd, Semiconductors reserves the right to change specifications without notice.
ABB Switzerland Ltd
Semiconductors
Fabrikstrasse 3
CH-5600 Lenzburg, Switzerland
Telephone
Fax
Email
Internet
+41 (0)58 586 1419
+41 (0)58 586 1306
[email protected]
www.abb.com/semiconductors
Doc. No. 5SYA1209-04 Jan. 03