EUPEC 2ED300C17-ST

EiceDRIVER™
2ED300C17-S
2ED300C17-ST
Dual IGBT Driver for
Medium and High Power IGBTs
Datasheet and Application Note
Prepared by : M.Hornkamp
Date of publication: 16.05.2003
Approved by: Reg.Nr.064-02
Revision: 3.0
SN: 23925
Status:
SN:24816
preliminary
eupec GmbH
Max-Planck-Straße 5
D-59581 Warstein
Author:Michael Hornkamp
Tel. +49(0)2902 764-0
Fax +49(0)2902 764-1150
Email: [email protected]
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Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
Passing on of this document or its contents to company external personnel requires written consent.
Usage and copying of the contents to other media is prohibited. Violations will be prosecuted for
damages. All rights reserved, including such arising from issue of patents or registration of trade marks or
design.
© eupec GmbH 2002. All rights reserved.
Correspondence of the contents of this document with the described hardware has been checked.
Discrepancies may exist nevertheless; no guaranty is assumed for total congruence. The information
contained in this document is subject to regular revision. Any alterations required will be incorporated in
the next issue. Suggestions for improvement are welcome. Changes of the document may occur without
prior notice.
Safety notice!
It must be prevented that children and the general public have access to the installed driver or can get into
proximity!
The driver may only be used for the purposes prescribed by the manufacturer. Inadmissible alterations
and use of spare parts and accessories not recommend by the manufacturer of the driver can cause fire,
electric shock and injuries.
This document has to be at the disposal of all users, developers and qualified personnel who are to work
with the driver.
If measurements and tests on the live device have to be carried out, then the regulations of the Safety
Code VBG 4.0 are to be observed, in particular § 8 “Admissible deviations during work on live parts“.
Suitable electronic devices are to be used.
Prior to installation and commissioning please read this document thoroughly.
• Commissioning is prohibited if there is visible damage by inappropriate handling or transport.
• Contact while uninstalled is permitted only with ESD protection.
• Install only without supply voltage.
• Always keep sufficient safety distance during commissioning without closed protective housing.
• Contact under live condition is strictly prohibited.
• Work after turn-off is not admissible until the absence of supply voltage has been verified.
• During work after turn-off it has to be observed that components heat up during operation. Contact
with these can cause burning.
• The drivers are mounted electrically and mechanically into a mother board by soldering. The mechanical
strength has to be verified by the user and, if necessary, assured with appropriate tests.
• The drivers are designed for use with eupec IGBT Modules type IHM, EconoPACK+, 62mm. In case of
ulterior use, safe operation cannot be guaranteed.
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Page 2
Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
General Information 2ED300C17-S:
This datasheet describes the dual channel IGBT driver 2ED300C17-S for industrial application and the
2ED300C17-ST for traction application. The Drivers are separated in two temperature classes –25°C
for the 2ED300C17-S and –40°C for the 2ED300C17ST. The electrical function and the mechanic
dimension are in both version similar. Only if there is a different in the types the 2ED300C17-ST is
called.
The 2ED300C17-S is one of the EiceDRIVERTM driver family. (eupec IGBT controlled efficiency
DRIVER). The 2ED300C17-S IGBT driver is designed for use with eupec IGBT modules of the 1200V
and 1700V series. Functions of the 2ED300C17-S such as the “soft shut down” or the VCEsat reference
curves have to be adapted to the individual modules. This is described in the following chapters.
The 2ED300C17-S is designed for applications with high safety and reliability requirements and aims
for power ratings of 75kW to 1MW.
To offer high interference suppression, +15V is generally used for control. The entire logic processing
is also done with +15V. The integrated transformer is separated into three sections:
Two pulse transformers and a dual channel DC-DC switch mode power supply. These are designed
such that they offer lowest coupling capacitances and high isolation stability.
The 2ED300C17-S is additionally equipped with a feed-back ”Sense” input. This input can optionally
be connected with the active clamping or di/dt and dv/dt control.
The clearance and creepage distances comply with VDE0110 and VDE0160 / EN50178 and are
designed for pollution degree 3. Materials of the transformer meet requirements of UL94V0. Protection
degree IP00.
To protect from undefined switching of IGBTs in case of a gate-emitter short circuit of another IGBT,
the supply voltage VA;B+; VA;B- is internally monitored in the driver for short circuit currents. In case of a
gate-emitter short the secondary circuit is interrupted and thus the primary voltage maintained.
Exclusion clause:
The datasheet is part of the eupec IGBT driver 2ED300C17-S. To guaranty safe and fault free
operation it is necessary to have read and understood this datasheet.
The eupec IGBT driver 2ED300C17-S is only intended for control of eupec IGBT modules. The
company eupec GmbH cannot warrant against damage and/or dysfunction if IGBT modules used not
produced by eupec.
In this context, eupec GmbH retains the right to change technical data and product specifications
without prior notice to the course of improvement.
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Page 3
Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
Chapter:
Page
•Safety notice
•General information
•Exclusion clause
•Contents
2
3
3
4
1.
1.2
1.3
1.4
1.5
1.6
1.7
1.8
1.9
1.10
Datasheet
•Features
•Key data
•Block diagram
•Inputs and outputs
•Pin configuration
•Maximum permissible values
•Characteristic values
•Max. switching frequency at different rated currents
•Mechanical dimensions
5
5
5
6
6
7
8
9
10
11
2.
2.1
The transformer
• Safe electrical isolation Protection Class II according to
EN50178
12
12
3.
3.1
3.1.1
3.2
3.3
3.4
3.5
3.6
3.7
3.8
3.9
3.10
3.11
3.12
Application of the 2ED300C17-S
•Power supply
•Use of the internal over-current shut-down
•Mode selection
•Interlock delay times
•Logic levels (reset; fault output)
•Signal level
•IGBT connection
•IGBT Shot circuit / IGBT overload shut down
•SSD “soft shut down”
•External fault input
•“Sense” input (SSD and active clamping)
•Additional output voltage / buffer capacitors
•Application example 2ED300C17-S
13
13
4.
4.1
4.2
4.3
General
Designation and symbols
Module internal gate resistors
Type designation
29
29
30
32
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14
15
16
17
17
20
23
25
25
27
28
Page 4
Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
1.2 Features
• Dual channel IGBT driver 2ED300C17-S
• For 1200V / 1700V eupec IGBT modules
• VCE sat monitoring
• “Soft Shut Down” for fault conditions
• Save electrical isolation according
to EN50178
• Integrated DC-DC SMPS
• High peak output current
• ±15V secondary drive voltage
• Short signal transition time
• Optional “Sence” function
• High RFI immunity
1.3 Key data
Isolation testing voltage
Visol pulse transformer and DC/DC
5000
VAC
±30
A
4
W
according to EN50178 protection class II
Max. output current:
IG per channel
Max. output power
PDC/DC per channel
Signal transition time
tpd (on); tpd (off)
<670
ns
Minimal pulse suppression
tmd turn on and turn off
400
ns
PWM drive voltage
Vin drive level for channel A and B
+15
V
Supply voltage
Operating voltage VDC to ground
+15
VDC
dv/dt stability
dv/dt ( * during test)
Operating temperature
direct on driver surface
Top
Operating temperature
direct on driver surface
Top
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50*
kV/µs
2ED300C17-S
-25 bis 85
°C
2ED300C17-ST
-40 bis 85
°C
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Page 5
Technical Information
EiceDRIVER™ 2ED300C17-S
1.4 Block diagram 2ED300C17-S
preliminary
EDFA
E. A
VCEsat
VCE sat A
Fault
Detection
Gate A
IN A
Dead
time
Pulse
Stage
CA
IN B
Pulse
Former
Softshut down
Undervoltage
Pulse
Memory
COM A
VA+
VASense A
Dead
time
CB
Sense A
DOCD
RC A
EDFA
E. B
VCEsat
VCE sat B
Fault
Detection
Logic
MODE
Fault
Detection
Gate B
Pulse
Stage
RESET
FAULT
FaultMemory
VDD
VDC
Supply
Voltage
Pulse
Former
Softshut down
Undervoltage
Pulse
Memory
COM B
VB+
VBSense B
DC/DC
Converter
DOCD
Control
GND
Sense B
RC B
1.5 Inputs and outputs 2ED300C17-S
IN A; IN B
PWM signal inputs for channel A and channel B
CA; CB
Inputs for external interlock delay time generation for channel A and B in half bridge mode
Mode
Input for operating mode selection. Direct mode GND; half bridge mode +15V
Reset
With reset and operating PWM signals the primary fault memory is reset. Reset has active high logic. A
high signal activates the reset.
Fault
The fault output indicates a fault. The fault output is open collector.
VDC
Supply for the DC-DC SMPS
VDD
Electronic supply
GND
GND is ground and reference point for all primary signals and the supply voltage
E.A; E.B
External fault input. Is used to set the fault memory by an external signal.
VCE sat A; B
Input for the saturation voltage monitoring
Gate A; B
Driver output to the IGBT module gate via an external gate resistor
COM A; B
COM A; B is connected to the auxiliary emitters of the IGBT module
VA+; VA- ; VB+; VB-
Non-isolated supply voltage for additional use and connection of the buffer capacitors
Sense
Control input for the optional di/dt or dv/dt control, setting of the soft shut down or active clamping
RC A; RC B
RC network for VCE sat reference curve
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Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
1.6 Pin configuration of the 2ED300C17-S
1 VDD
2 VDD
3 VDD
4 Fault
5 Reset
6 CA
7 IN B
8 CB
9 Modus
10 Fault
11 IN A
12 GND
13 GND
14 VDC
15 VDC
16 VDC
17 VDC
18 VDC
19 GND
20 GND
21 GND
22 GND
23 GND
Gate A 45
Gate A 44
COM A 43
COM A 42
VA+ 41
VA- 40
Sense A 39
RC A 38
Vce sat A 37
E. A 36
Emitter
Sense
Collector
Csup
Gate
RSSD
CSA
RSA
2ED300C17-S
Gate B 33
Gate B 32
COM B 31
COM B 30
VB+ 29
VB- 28
Sence B 27
RC B 26
Vce sat B 25
E. B 24
Emitter
Sense
Collector
Csup
Gate
RSSD
CSB
RSB
Figure 1.6 Pin configuration of the 2ED300C17-S
Pin
Label
Function
Pin
Label
Function
1
VDD
+15V for electronics primary
2
VDD
3
VDD
+15V for electronics primary
45
Gate A
Gate channel A
+15V for electronics primary
44
Gate A
Gate channel A
4
5
Fault
Fault output
43
COM A
Reference point A
Reset
Logic level to reset channel A and B
42
COM A
Reference point A
6
CA
Delay time ch. A “half bridge mode“
41
VA+
+16V External buffer capacitor
7
IN B
PWM input B
40
VA-
-16V External buffer capacitor
8
CB
Delay time ch. B “half bridge mode“
39
Sense
SSD / clamping input
9
Mode
Mode selection
38
RC
Reference RC network channel A
10
Fault
Fault output
37
VCE sat
Collector sense channel A
11
IN A
PWM input A
36
E. A
External fault input channel A
12
GND
Ground for electronics primary
35
Physically non existent
13
GND
Ground for electronics primary
34
Physically non existent
14
VDC
+15V for SMPS
33
Gate B
Gate channel B
15
VDC
+15V for SMPS
32
Gate B
Gate channel B
16
VDC
+15V for SMPS
31
COM B
Reference point B
17
VDC
+15V for SMPS
30
COM B
Reference point B
18
VDC
+15V for SMPS
29
VB+
+16V External buffer capacitor
19
GND
Ground for SMPS
28
VB-
-16V External buffer capacitor
20
GND
Ground for SMPS
27
Sense
active- clamping / SSD
21
GND
Ground for SMPS
26
RC
Reference RC network channel B
22
GND
Ground for SMPS
25
VCE sat
Collector sense channel B
23
GND
Ground for SMPS
24
E. B
External fault input channel B
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Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
1.7 Maximum permissible values
Supply voltage VDC
Maximum primary supply voltage
+16
V
PWM signal input voltage Vin
Max. voltage on inputs IN A; IN B
±20
V
Logic signal input voltage ViH
Max. voltage (Mode; Reset)
±20
V
Logic signal output current IOC
Fault output; max. continuous current open
collector
20
mA
Peak output current ON IG on
Max. driver peak output current
+30
A
Peak output current OFF IG off
Max. driver peak output current
-30
A
Output current summed
maximum |Iout| AV
Average value of the summed output
current values per channel 1)
133
mA
Maximum output power PDC/DC
PDC/DC channelA + channel B
8
W
Maximum IGBT voltage VCES
Maximum collector-emitter voltage on IGBT
1700
V
Isolation test voltage Visol IO
Input- Output (RMS, 50Hz, 1s)
5000
V~
Isolation test voltage Visol 12
Input A- Output B (RMS, 50Hz,1s)
2250
V~
Surge voltage test Visol Su
Surge test according to EN50178
Input to Output
9600
V
Gate resistor Rg min
Min. gate resistor (module internal +
external gate resistor)
1
Ω
Gate capacity Cies max
Maximum IGBT gate capacity
350
nF
dv/dt
Voltage slew rate
secondary to primary site
50*
kV/
µs
Top
Operating temperature 2ED300C17-S
-25......+85
°C
Top
Operating temperature 2ED300C17-ST
-40 .....+85
°C
Tsto.
Storage temperature
-40 .....+85
°C
fs max switching frequency
Max. switching frequency(Top<65°C PDC/DC=8W)
60’000
Hz
Supply current IDC max.
Maximum continue permissible current draw
of the dual driver
533
mA
tTD min min. interlock delay time
Factory set delay time in half-bridge mode
1,6
µs
d
Maximum duty cycle
100
%
duty cycle
*
during test
•
133mA refer to gate input and additive ancillary voltage (see chapter 2.10)
|Iout| AV = |IG |AV+Iout
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Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
1.8 Characteristic values
All values at +25°C
Min.
Typ.
Max.
VDC supply voltage primary DC-DC
+14
+15
+16
IDC current draw DC-DC
+15V
80
IDC current consumption DC-DC (VDC=+15V PDC/DC=8W)
mA
8
VDD supply voltage electronics
+14
IDD current draw electronics
+15
+16
W
+15V
60
0
V
mA
8
switching frequency
V
525
PDC-DC power DC-DC SMPS
fS
Recommend.
kHz
Tpd on
signal transition time switch on
670
ns
Tpd off
signal transition time switch off
580
ns
tdif transition time differences
50
ns
tmd
Minimal puls suppression
400
ns
d
duty cycle
100
0
Reference voltage for the VCE sat – monitoring
VCEstat
2
Threshold logic and signal level
(IN A/B; Reset; Mode) VLevel
9
+8
Reactivation after fault condition
and IN A/B Low2) tBK
50
Interlock delay time in half-bridge mode tTD4)
1,6
%
83)
V
+15
V
60
ms
µs
Coupling capacity primary/secondary Cps
18
pF
Coupling capacity sec. channel A to B Css
15
pF
1) “Conditions
to be defined“
chapter 2.4
3) See chapter 2.7
4) See chapter 2.3
5) See chapter 2.6
2) See
Max. switching frequency:
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I
(mA)
f S max . = outAV
QG ( µC ) ⋅1,5
fmax= maximum switching frequency
IoutAV= average cont. output current per channel
QG= maximum IGBT gate charge at 30V
1.5= tolerance factor
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Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
1.9 Maximum switching frequency with different module nominal currents IGBT3
1200V IGBT3
All values by +25°C
4
* Target values
3,5
3
Drive power in W
2,5
2
150A
225A
1,5
300A
450A
1
600A
800A
0,5
1200A
1600A
0
0
5000
10000
15000
20000
25000
30000
Switching frequency in Hz
1700V IGBT3
All values by +25°C
4
* Target values
3,5
Drive power in W
3
2,5
2
150A
225A
1,5
300A
450A
1
600A
800A
0,5
1200A
1600A
0
0
5000
10000
15000
20000
25000
Switching frequency in Hz
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30000
Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
1.10 Mechanical dimensions
2.95mm
RM2.54mm
RM2.54mm 2.95mm
24
45
28mm
72 mm
27 mm
1
60,5 mm
23
RM2.54mm
2.31mm
2.31mm
Clearance distance and creep page Primary/
Secondary
>15
mm
Clearance distance Secondary/ Secondary
>6
mm
Creep page Secondary/ Secondary
>14
mm
Max.25mm
20mm
d=1mm
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Page 11
PCB
d=1mm
Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
2. The transformer
2.1 Safe electrical isolation Protection Class II according to EN50178
The safe isolation between primary and secondary side of the two transformers and
the switch mode power supply is the basis for the 2ED300C17-S.
Highly insulated coil wires, core insulated ferrites and a special sealing compound
(UL94 V-0) are used for this purpose. The design makes sure that all windings are
physically separated from each other. There are no overlapping primary and
secondary windings. The winding connections are terminated directly to the pins
which are cast into the housing. All that is contained in a plastic housing certified to
UL 94.
9
16
8
1
Figure 2.1 Complete transformers with cores in position
The transformer is designed for use in industrial and traction applications. The test
voltage applied between all inputs and all outputs is 5kV AC for 1 second. The test
voltage applied between the secondaries is 2.25kV AC for 1 second. (EN50178
Table18) (Individual test)
The insulation test is completed by the surge voltage test stipulated by EN50178.
Surge voltage test according to (EN50178 table 17) is 1.5/50µs with 9.6kV.
The partial discharge extinction voltage stipulated by the standard (EN50178 table19)
is above 1763V crest value (type test).
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Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
3 Application of the 2ED300C17-S:
3.1 Power supply
The 2ED300C17-S has an integrated DC-DC switch mode inverter, which generates
the required secondary voltages. The generated voltages are for the top and bottom
channel with +15V primaries each ±16V secondaries.
Hence the 2ED300C17-S only requires one external power supply of +15V. The
2ED300C17-S is operated on a stabilized +15V (±1V) supply. It is distinguished
between VDD and VDC. All inputs are switched with+15V,where VDC should be
additionally stabilized by a capacitor CDC (see figure 3.1). This stabilizing capacitor CDC
should be 220µF minimal.
All GND pins have to be connected. To prevent a ground loop there is no internal
connection of the DC-DC SMPS ground and the primary electronics.
10R
1µF
+15V
CDC
1 VDD +15V
2 VDD +15V
3 VDD +15V
4 Fault A
5 Reset
6 CA
7 IN B
8 CB
9 Modus
10 Fault B
11 IN A
12 GND
13 GND
14 VDC +15V
15 VDC +15V
16 VDC +15V
17 VDC +15V
18 VDC +15V
19 GND
20 GND
21 GND
22 GND
23 GND
Note!
If the driver is turned on with +15V, a
low voltage fault may be tripped
depending on the voltage slew rate. This
will be reset after 50ms if both signal
levels IN A and IN B remain Low during
this time.
Note!
No potential difference greater than 20V
may occur between VDD and VDC.
Figure 3.1 Pin configuration of +15V voltage supply
Note!
The 2ED300C17-S features secondary under-voltage monitoring. If the
secondary supply voltage drops below typical +12V or -12V, a fault condition
will occur which turns off the driver and is transferred to the primary as well.
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Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
3.2 Mode selection
The 2ED300C17-S features two operating functions to drive eupec IGBT modules.
These are the direct mode and the half-bridge mode.
• The direct mode:
In this mode there is no link between the two channels of the 2ED300C17-S. Both
channels IN A and IN B are working independently from each other and may both be
turned on at once. The inputs IN A and IN B are switched with +15V PWM signals.
The direct mode is activated by taking pin 9 ”Mode selection” to GND (e.g.: pin 12/13).
The inputs CA pin 6 and CB pin 8 are not connected.
Note!
In the direct mode the inputs CA and CB may not be connected to +15V or GND.
For EMC reasons it is recommended to connect the inputs CA and CB with 470pF
to GND.
• The half-bridge mode:
This mode generates an interlock time between the two channels of the 2ED300C17-S.
I.e. there is always only one channel active. The interlock time between the switching
events may be selected. This is done with the inputs CA pin 6 and CB pin 8.
The half-bridge mode is activated by taking pin 9 ”Mode selection” to VDD (pin 1/2/3).
The inputs IN A and IN B are switched with PWM inputs.
Explanation:
There is always only one channel turned on. If there is a high signal on one channel,
this is turned on after the interlock time has ended. If during this time there is a high
signal for the second channel it will be ignored until the first turned on channel has
turned off.
PWM
IN A
+15V
0V
PWM
IN B
+15V
0V
Gate A
+15V
-15V
Gate B
+15V
-15V
Figure 3.2 Switching diagram with interlock delay times
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Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
3.3 Interlock delay times
In half-bridge mode the 2ED300C17-S generates a minimal internal interlock delay
time between the two channels. This minimal interlock time tTD is preset to 1,6 µs. By
adding a capacitance to the two inputs CA and CB this interlock time is extended and
adapted to the requirements of the application. The capacitance is externally added
between CA and CB to GND (see page 7 – 1.6 Pin configuration).
The capacitance for the required interlock time is derived from the following table:
Del. time TTD
CA / CB
1,6µs
n.c.
2µs
47pF
2,4µs
100pF
3.4µs
220pF
4,3µs
330pF
5,4µs
470pF
9,6µs
1nF
NOTE !
It is not permit to connect the inputs CA and CB
direct to a voltage potential.
NOTE !
The tolerance of the interlock delay times
depends mainly on the tolerance of the external
capacities. This needs to be considered when
choosing the capacitors!
Table 3.3 Interlock delay time settings
Pin 6 CA
Pin 8 CB
Ca Cb
Primary
Side
Secondary
Side A
Pulse
Transformer
DC/DC
Pin 12 GND
Pin 13 GND
Secondary
Side B
Figure 3.3 Connection of the external capacitors to increase the interlock times
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Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
3.4 Logic level
The term “logic level” concerns the fault output and the reset input as well as the input for
operating mode selection described in chapter 3.2.
• Logic inputs
The two inputs (reset and mode) may be stressed with a maximum voltage of 20V. The
switching threshold is at 8V, so the existing +15V offers itself as switching signal.
1) Mode: see chapter 3.2
2) Reset: The driver can be reset via the reset input after a fault has been indicated. The
reset input is active high, i.e. a high signal activates the reset. Logic signal level is by
8V.
If reset is used by the PWM inputs IN A and IN B, the reset input is inactive and pin 5
(Reset) has to be permanently connected to GND
If both PWM signals are “low” for more than 39ms the driver is reset.
• Logic outputs
The driver core recognizes short circuit current faults of the IGBTs and faults of the supply
voltage. Additionally the 2ED300C17-S features an external fault input. If a fault is
detected through the VCE sat monitoring, an under-voltage or the external fault input, the
driver core is immediately turned off. With these faults on the secondary side, the IGBT is
shut down via a soft turn-off. Each fault is stored until a reset signal on Pin 5 is present.
The reset is also activated when the input signal on both channels is low for more than
39ms.
Indication of a fault occurs in any case via a common fault line on the logic output FAULT.
The fault is brought out twice via Pin4 and Pin10.
These outputs are configured as open collector. The outputs can operate at up to 20V
and can switch a maximum of 20mA .
If a fault is recognized the internal transistor switches and pulls the fault output to GND.
+15V
+15V
1 VDD +15V
2 VDD +15V
3 VDD +15V
4 Fault
5 Reset
6 CA
7 IN B
8 CB
9 Modus
10 Fault
11 IN A
GND
Figure 3.4 Fault output
Note! The fault outputs are internally connected.
There is only one fault output - doubled up.
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Page 16
Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
3.5 Signal level
In both the direct mode and the half-bridge mode the input IN A of the 2ED300C17-S
controls channel A, and input IN B controls channel B. The inputs feature a SchmittTrigger and an active high logic. A high level turns the IGBT on and a low level turns it
off.
The two signal inputs may be operated with a maximum of 20V per channel. Brief
negative peaks of equal voltage will not lead to damage of the inputs. The switching
threshold is at +8V to GND.
The input impedance is 3.3kOhm for each channel. For long cables it may be
necessary to connect an external burst suppression network.
Note:
The 2ED300C17-S features a minimal pulse suppression. Pulses with less than
400ms will be suppressed by the driver.
1 VDD +15V
2 VDD +15V
3 VDD +15V
4 Fault
5 Reset
6 CA
7 IN B
8 CB
9 Modus
10 Fault
11 IN A
12 GND
13 GND
14 Vdc +15V
10µH
PWM B
10µH
PWM A
3.6 IGBT connection
Figure 3.5 Input signal level
The 2ED300C17-S features two independent channels to drive the IGBTs. It is
possible to drive individual IGBTs, single IGBT-modules or IGBT-modules connected
in parallel.
The maximum size of the IGBT-modules depends mainly on the IGBT input
capacitance and on the switching frequency. This dependency is described on page
9 for KE3 modules.
When considering the gate currents, note that these are not determined by the
external gate resistors alone. Many eupec IGBT modules have internal gate resistors
(See chapter 5). Additionally, the 2ED300C17-S features a low output impedance.
Hence a gate current calculated via the external gate resistor will never be realized
in practice. An approximation for the drive power and peak current can be achieved
with:
•Driver power
P G = f ⋅ ∆ V GE
2
⋅C
ies
⋅3
P = P DD + PG
• Max. driver current
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IG
max
=
∆ V GE
R G (min)
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f = switching frequency
Cies = input capacity (datasheet)
PDD = driver dissipation
∆ V = 30 V at ± 15 V
RG(min)=RG extern+RG intern
Page 17
Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
•Gate connection
The gate of the IGBT is connected to Gate A or Gate B via the external gate resistor.
The associated auxiliary emitter is connected directly to the COM outputs.
The gate output voltage is ±15V with respect to COM A and COM B (considering
chapter 3.1).
By utilizing the external gate resistors it is possible to realize turn-on and turn-off with
different gate resistances. Additionally to the gate resistor a gate-emitter resistor and
gate clamping should be used. These would be placed between the gate and the aux.
emitter. As RGE a resistor <10kOhm is recommended. The gate clamping is done with
Zener diodes or suppressor diodes with a break-over voltage of less than 18V. These
diodes prevent the gate voltage to rise to inadmissible levels through parasitic effects
(e.g. Miller capacity).
The external gate resistors are defined in the eupec IGBT datasheet.
RGA
Gate A 45
Gate A 44
COM A 43
COM A 42
VA+ 41
VA- 40
Sense A 39
RC A 38
Vce sat A 37
E. A 36
Gate B 33
Gate B 32
COM B 31
COM B 30
VB+ 29
VB- 28
Sense B 27
RC B 26
Vce sat B 25
E. B 24
RGE
RGB
RGE
Figure 3.61 Gate connection
Note!
The use of different gate resistors for turn-on and turn-off with field stop IGBTs to
change the di/dt (KE3 modules) is not necessary.
With field stop IGBTs only the di/dt turn-on behavior is influenced by the gate resistor.
See chapter 3.10 ”sense”. The dv/dt for turn-on and turn-off is still set with the gate
resistor.
RG ein
RG aus
Gate A 45
Gate A 44
COM A 43
COM A 42
VA+ 41
RGE
Figure 3.62 Gate connection with RG on and RG off
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Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
•Collector connection
The 2ED300C17-S is able to measure and evaluate the voltage between collector and
emitter of an IGBT. This is used to recognize a short circuit and then shut-down. For
the optional function of DVRC or active clamping the connection to the collector is
also required.
For the short circuit shut-down function the auxiliary collector is connected to VCEsat A
or VCEsat B. To block the high DC-link voltage during shut-down a diode Dx with high
reverse blocking voltage has to be connected between the collector and the “Vce sat“
input. The reverse blocking capability of these diodes should be higher than the IGBTmodule voltage (1200V/1700V). Further the diode has to follow the switching
frequency and therefore has to be accordingly fast. Two or three diodes in series is an
option to achieve the required blocking capability.
Application and adjustment of the short circuit shut-down is described in detail in the
next chapter 3.7.
DA 2x UF4007
RGA
Gate A 45
Gate A 44
COM A 43
COM A 42
VA+ 41
VA- 40
Sense A 39
RC B 38
Vce sat A 37
E. A 36
Gate B 33
Gate B 32
COM B 31
COM B 30
VB+ 29
VB- 28
Sense B 27
RC A 26
Vce sat B 25
E. B 24
RGE
1nF
DB 2x UF4007
470R
RGB
RGE
1nF
470R
Figure 3.63 Collector connection for V
measurement
ce sat
Note!
The RGE, the gate-emitter clamping diodes, the gate resistor and the collector
diodes DX should be placed in the closest possible vicinity of the module.
Note!
If wire links are used between the drivers and the IGBTs the gate lead should
be twisted together with the respective emitter and collector leads. Where
these connections should be as short as possible. Lengths of more than 20cm
are to be avoided.
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Page 19
Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
3.7 IGBT short circuit and over-current shut-down with SSD “soft shut down“
A short circuit or over-current is detected by the integrated VCE measurement in the
2ED300C17-S (see chapter 3.6). The 2ED300C17-S measures the VCE voltage while the
IGBT is turned on. If the VCE rises above the preset reference voltage during this period,
a fault is triggered and the IGBT is turned off via the internal soft shut-down. For eupec
IGBT-modules with NPT and FS-technology the soft shut-down reduces the voltage
over-shoot by a slower turn-off.
•The reference curve
is only adjustable via an external RSX and CSX . With RSX the reference voltage is set and
with CSX the reference time.
The resistor and the capacitor are connected between RC A and COM A or RC B and
COM B . The reference time elapses directly with the turn-on of the respective driver
side (See figure 3.7.2)
V
Vref Reference curve
Gate A 45
Gate A 44
COM A 43
COM A 42
VA+ 41
VA- 40
Sense A 39
RC B 38
Vce sat A 37
E. A 36
CSA
RSA
Vref=f(RSX)
Gate B 33
Gate B 32
COM B 31
COM B 30
VB+ 29
VB- 28
Sense B 27
RC A 26
Vce sat B 25
E. B 24
CSB
PWM
RSB
t
Vref=f(CSX)
t
Figure 3.7.2 Reverence curve
Figure 3.7.1 RSX and CSX connection to adjust the reference curve
Reference
Voltage Vref
CSX=
0 pF
CSX=
100 pF
CSX=
220 pF
CSX=
470 pF
CSX=
1 nF
7
2V
RSX= 2 kΩ
0,5µs
1,5 µs
3 µs
5 µs
4V
RSX= 5,4 kΩ
1 µs
3 µs
4 µs
9 µs
6V
RSX= 12 kΩ
1 µs
4 µs
6 µs
8V
RSX= 32 kΩ
1 µs
5 µs
7 µs
9V
RSX= 70 kΩ
1 µs
5 µs
7 µs
Table 3.7 gives reference voltage Vref and reference time tref until the reference voltage is reached.
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Page 20
Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
A comparator inside the 2ED300C17-S compares the voltage at the VCE sat input with the
reference voltage Vref. The maximum VCE voltage at the comparator will be 10V. With the
turn-on of the IGBT the VCE voltage drops to its threshold value depending on the load
current IC. To suppress commutation effects during turning on the IGBT there is the
settable reference curve Vref. This drops, depending on the external CSX and RSX network,
from 16V to the set voltage level. If the VCE voltage rises above the reference voltage at
any time, a fault is tripped and the driver is locked.
The various different operating conditions are depicted in the four cases below. If the fault
occurs, the IGBT is turned off via the SSD (Soft Shut Down) function.
+15V
+15V
Fault
+10V
+10V
Vref
Vref
+5V
+5V
VCE
VCE
0V
0V
Case 2. IGBT turns on too slowly
or reference time is too short
Case 1. Usual case
+15V
+15V
Fault
+10V
VCE
Fault
VCE
+10V
Vref
Vref
+5V
+5V
0V
0V
Case 3. Short circuit during operation
Case 4. Short circuit during turn-on
Figure 3.7.3 Different faults depicted
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Page 21
Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
• Trigger suppression for the Vce sat measurement
To vary the sensitivity of the VCE , the 2ED300C17-S uses an RC timing network. This
network is used to set the sensitivity of the VCE SAT monitoring as required by the
individual application. One has to keep in mind that this RC network is a timing function.
Accordingly, reaching the reference voltage and in this connection the detection of the
temporal short circuit current in the IGBT depend on the charging process of the CVCE
capacitor. This can easily be defined by measuring in front of CVCE once and in
comparison to this V ce sat x directly at the input.
The RC combination is able to prolong the operating time till the IGBT switches off in
case of a short circuit.
This is to say that in addition to reference time treff (table 3.7) and SSD cycle time
tSD=5µs and system cycle time tSD=1µs, the trigger suppression time has to be taken into
account.
As a standard, a value of RVCE =470R and CVCE =1nF is recommended.
Should the VCE sat monitoring react too sensitively the CVCE value can be increased.
This of course prolongs the trigger time of the short circuit turn-off.
In a contrary case, it is certainly recommended to decrease the CVCE value or the RVCE
value.
One always has to make sure that the short circuit across the IGBT is switched off after
10µs.
DA 2x UF4007
RGA
Gate A 45
Gate A 44
COM A 43
COM A 42
VA+ 41
VA- 40
Sense A 39
RC B 38
Vce sat A 37
E. A 36
Gate B 33
Gate B 32
COM B 31
COM B 30
VB+ 29
VB- 28
Sense B 27
RC A 26
Vce sat B 25
E. B 24
RGE
CVCE 1nF
RVCE 470R
DB 2x UF4007
RGB
RGE
CVCE 1nF
RVCE 470R
Figure 3.7.4 Trigger suppression of the Vce sat measurement
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Page 22
Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
3.8 SSD “Soft Shut Down“
The SSD “Soft Shut Down“ is used to softly shut down the IGBT if a fault occurs. This is
sensible in order to avoid destruction of the IGBT due to high voltage overshoots during
turn-off. If set correctly the SSD will reduce the turn-off di/dt of all eupec IGBT products
and hence the voltage overshoot during fault conditions.
The “Soft Shut Down“ is set with resistor RSSD. This resistor is externally connected
between Sense and –16V (see figure 3.8.1).
Gate A 45
Gate A 44
COM A 43
COM A 42
VA+ 41
VA- 40
Sense A 39
RC A 38
Vce sat A 37
E. A 36
RSSD
CSA
RSA
CSA
RSA
2ED300C17-S
Gate B 33
Gate B 32
COM B 31
COM B 30
VB+ 29
VB- 28
Sence B 27
RC B 26
Vce sat B 25
E. B 24
RSSD
Figure 3.8.1 Connection of RSSD
The “Soft Shut Down“ has to be adapted to the IGBT type used. Since the turn-off
behavior and the resulting voltage overshoot depends on the IGBT type and the
construction of the entire application, the resistance of the RSSD resistor has to be found in
a practical manner.
As guidance one can use the module FS450R17KE3 with an RSSD = 10kΩ.
IGBT modules with a greater input capacitance Cies will need a lower RSSD value, IGBT
modules with a lower input capacitance Cies will need a greater RSSD value. The
dissipation of the resistor is calculated as follows:
PSSD [W ] =
1024
RSSD
If a fault is recognized and the “Soft shut down“ is activated, the capacitances of the
internal bipolar- output stage go through the charge reversal and thus the IGBT input
capacitance Cies and the Miller capacitance Cres are discharged slowly. This process is
limited to tSD= 4µs. After this time the output of 2ED300C17-S turns off hard.
The driver has to be reactivated by a “Reset“ (see chapter 3.4 logic levels).
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Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
Note!
The “Soft Shut Down“ may slightly increase the VGE. Hence the gate clamping described
in chapter 3.6 IGBT Connection has to be observed.
Note!
eupec IGBT modules are generally designed for short circuits of up to tP≤ 10µs.
With the calculation of the external network RSX and CSX make sure not to exceed
this time.
tP-tSD-tsys= tref
tP= short circuit time IGBT 10µs
tSD= SSD transition time 5µs
tsys= system transition time 1µs
tref= reference time (+ Trigger suppression for the Vce sat )
Note!
The “Soft Shut Down” is not 100% protection from voltage overshoots during fault turnoff!
Should a short circuit occur and at the same time the natural PWM puls go to Low Level
the SSD can not be commenced. This case is rare but can occur. Active Clamping will
then protect against over-voltage (see 3.10).
VGE
1100V
IC
VCE
VµC
Figure 3.8.2: Short circuit turn-off at 1100V with SSD
The short circuit turn-off depicted in Fig. 3.8.2 clearly shows the course of the
Gate-Emitter voltage with SSD.
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Page 24
Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
3.9 External fault input
The 2ED300C17-S features an external fault input E.A and E.B. These are used to set
the internal fault memory by a high gate output signal and to trigger a fault. The fault
inputs E.A and E.B have an active high logic. Switching level is at 5V, so that a high
signal will trigger a fault. The maximum level for the input is VA+ or VB+ referenced to the
adjoining COM.
This input is considered for example to detect an over-temperature and/or over-current
and so to shut down the driver. Note that the inputs E.A and E.B may rise up to DClink potential!
Note !
If the inputs E.A and/or E.B are not used, they have to be connected to COM A /
COM B.
3.10 “Sense“ input (SSD “Soft Shut Down“, optional DVRC or active clamping)
A special feature of the 2ED300C17-S is the ability to directly manipulate the driver output
stage. This is a bipolar output stage externally accessible via the ”Sense” input.
This is necessary to limit the voltage overshoot through the di/dt during turn-off of the
IGBTs. (see also chapter 3.8 SSD).
With a additional circuit and by using the sense input it is possible to control this di/dt in
every operating point during turn-off of the IGBT and hence prevents inadmissibly high
turn-off voltage overshoots.
RGA
Gate A 45
Gate A 44
COM A 43
COM A 42
VA+ 41
VA- 40
Sense A 39
RC B 38
Vce sat A 37
E. A 36
Gate B 33
Gate B 32
COM B 31
COM B 30
VB+ 29
VB- 28
Sense B 27
RC A 26
Vce sat B 25
E. B 24
RGE
RGB
RGE
Figure 3.10.1 Utilization of the ”Sense” input
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Page 25
Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
A further application of the ”Sense” input is the use of an active clamping** with
direct feedback to the output stage. In this case the Zener diodes used are only
minimally loaded which makes for example transile diodes possible.. This can then
be combined with an active clamping directly to the gate.
SM6T220A
** not yet tested with all
IGBT modules!
RGA
Gate A 45
Gate A 44
COM A 43
COM A 42
VA+ 41
VA- 40
Sense A 39
RC B 38
Vce sat A 37
E. A 36
Gate B 33
Gate B 32
COM B 31
COM B 30
VB+ 29
VB- 28
Sense B 27
RC A 26
Vce sat B 25
E. B 24
RGE
SM6T220A
RGB
RGE
Figure 3.10.2 Utilization of the “Sense“ input with active clamping
The standard application with the 2ED300C17-S is the “Soft Shut Down“. This is a quasilinear turn-off during fault condition.. The “Soft Shut Down“ has to be adapted to each
module type. For this an external resistor RSSD is connected between “Sense“ and –16V.
(See chapter 2.8 Short circuit/over-current turn-off with “Soft shut down“ )
Note!
The “Soft shut down“ is the standard setting of the 2ED300C17-S. For this a
resistor RSSD should be connected between “Sense and –16V. If active clamping is
used the RSSD can also be utilized.
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Page 26
Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
3.11 Additional output voltage / buffer capacitors
Depending on the utilization of the internal DC-DC SMPS an additional use of the
secondary supply voltage is possible. This is made available on the outputs +16V and –
16V and is referenced to the respective COM.
This voltage is potential separated to the primary side. The ground COM is here
referenced to the emitter of the respective IGBT.
The outputs +16V and –16V are also used to connect buffer capacitors Csup. These
prevent voltage drops with high pulse currents.
The buffer capacitors should be placed in closest vicinity to the 2ED300C17-S and must
always be used.
RGA
Gate A 45
Gate A 44
COM A 43
COM A 42
+16V 41
-16V 40
Sense A 39
RC B 38
Vce sat A 37
E. A 36
Gate B 33
Gate B 32
COM B 31
COM B 30
+16V 29
-16V 28
Sense B 27
RC A 26
Vce sat B 25
E. B 24
Csup
RGE
RGB
RGE
Csup
Figure 3.11 2ED300C17-S with external buffer capacitors
Note!
The additional electrolytics Csup always have to be connected. When selecting
these capacitors take note of the high ripple current requirement. Meaning, only
caps with low impedance are to be used.
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Page 27
Technical Information
10µH
Fault A/B
Reset
PWM B
10µH
100nF
PWM A
+15V
1µF
2k2
10R
470µF
Gate B 33
Gate B 32
COM B 31
COM B 30
VB+ 29
VB- 28
Sense B 27
RC B 26
Vce sat B 25
E. B 24
2ED300C17-S
Gate A 45
Gate A 44
COM A 43
COM A 42
VA+ 41
VA- 40
Sense A 39
RC A 38
Vce sat A 37
E. A 36
220µF
1nF
470R
560pF
220µF
1nF
470R
560pF
SM6T220A
RSSD 10K
SM6T220A
12K
RSSD 10K
220µF
12K
220µF
3.12 Application example 2ED300C17-S
1 +15V
2 +15V
3 +15V
4 Fault
5 Reset
470pF
6 CA
7 IN B
8 CB
9 Modus
10 Fault
11 IN A
12 GND
13 GND
14 +15V
15 +15V
16 +15V
17 +15V
18 +15V
19 GND
20 GND
21 GND
22 GND
23 GND
Fig. 3.12 Commissioning circuit in the direct mode:
(Both channels can be switched independently)
2x UF4007
1,5KE18
RGate
10k
2x UF4007
RGate
10k
1,5KE18
Page 28
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www.eupec.com
preliminary
EiceDRIVER™ 2ED300C17-S
Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
4.1 Designations and symbols
Cps
CSS
Csup
Cies
Cies max
CSX
CVCE
COM
d
DVRC
DOCD
dv/dt
di/dt
EDFA
fS
fS max
IC
IDC
IDD
IG
IG on
IG off
I0
IOC
Iout
|IG| AV
|Iout| AV
IDC max
PDC/DC
PSSD
PDD
PG
QG
Rg
Rg min
Rg intern
Rg extern
RGE
RSSD
coupling capacity primary/secondary
coupling capacity sec. channel A to B
buffer capacitor
IGBT input capacity
max. admissible IGBT- Gate- capacity
reference capacitor for time setting
VCE sat trigger suppression
reference point
duty cycle
Dynamic Voltage Rise Control
dynamic over-current detection
voltage slew rate
current rise time
logic external fault input
switching frequency
max. admissible switching frequency
IGBT collector current
current draw DC-DC
current draw electronics
output peak current
output peak current “On“
output peak current “Off“
Quiescent current
logic signal output current
output current of VA;B±
summed average gate current
summed average output current
maximum primary current draw
peak output power
power of the SSD resistor
driver power dissipation
maximum gate power dissipation
Max.IGBT gate charge at 15V
Gate resistor
Minimum gate resistor
IGBT Chip internal gate resistor
IGBT external gate resistor
(Datasheet)
Gate- Emitter resistor
Soft Shut Down resistor
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RSX
RVCE
SSD
tTD
tTD min
tBK
tdif
tmd
tP
tref
tsd
tsys
tpd
Top
Tstg
VLevel
VDD
VDC
ViH
ViHS
Vin
Visol
Visol IO
Visol 12
Visol Su
VCE
VCE sat
VCE stat
Vref
VGE
VA;B+
VA;B-
Reference resistor voltage setting
VCE sat trigger suppression
Soft Shut Down
interlock delay time
minimum interlock delay time
reactivating time
transition time difference
minimal pulse suppression
short circuit time
reference time DOCD
transition time SSD
system transition times
signal transition time
operating temperature
storage temperature
logic switching level
supply voltage electronics primary
primary DC/DC supply voltage
maximum voltage of the logic levels
switching threshold logic signals
signal input voltage
isolation test voltage
isolation test input- output
isolation test output A- output B
surge test voltage input- output
IGBT collector- emitter voltage
IGBT saturation voltage
VCE sat monitoring reference voltage
reference voltage of the DOCD
Gate- Emitter voltage
secondary positive voltage
secondary negative voltage
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Page 29
Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
4.2 Internal module gate resistor RG intern
FP10R12KE3
FP15R12KE3
FP25R12KE3
FP40R12KE3
FP50R12KE3
FP75R12KE3
FS25R12KE3
FS35R12KE3
FS50R12KE3
FS75R12KE3
FS100R12KE3
FS150R12KE3
FS150R12KE3 G
FS225R12KE3
FS300R12KE3
FS450R12KE3
0 Ohm
0 Ohm
8 Ohm
6 Ohm
4 Ohm
10 Ohm
8 Ohm
6 Ohm
4 Ohm
10 Ohm
7.5 Ohm
5 Ohm
1.33Ohm
3.33 Ohm
2.5 Ohm
1.66 Ohm
FF150R12KE3 G
FF200R12KE3
FF300R12KE3
FD200R12KE3
FD300R12KE3
DF200R12KE3
DF300R12KE3
FZ300R12KE3
FZ400R12KE3
FZ600R12KE3
FF600R12KE3
FF800R12KE3
FF1200R12KE3
FZ1200R12KE3
FZ1600R12KE3
FZ2400R12KE3
FZ3600R12KE3
5 Ohm
3.75 Ohm
2.5 Ohm
3.75 Ohm
2.5 Ohm
3.75 Ohm
2.5 Ohm
2.5 Ohm
1.875 Ohm
1.25 Ohm
1.25 Ohm
0.94 Ohm
0.62 Ohm
0.62 Ohm
0.46 Ohm
0.3 Ohm
0.2 Ohm
Table 4.2.1 RG intern KE3 1200V modules
FS150R17KE3G
FS225R17KE3
FS300R17KE3
FS450R17KE3
FF200R17KE3ENG
FF300R17KE3ENG
FZ400R17KE3ENG
FZ600R17KE3ENG
3.17 Ohm
2.83 Ohm
2.5 Ohm
1.67 Ohm
2.375 Ohm
2.13 Ohm
1.19 Ohm
1.06 Ohm
Table 4.2.2 RG intern KE3 1700V modules
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Page 30
Technical Information
EiceDRIVER™ 2ED300C17-S
BSM50GD120DN2G
FS75R12KS4
BSM75GD120DLC
BSM75GD120DN2
BSM100GD120DN2
BSM100GD120DLC
FS100R12KS4
BSM100GT120DN2
BSM150GT120DN2
BSM200GT120DN2
BSM150GT120DLC
BSM200GT120DLC
BSM100GAL120DN2
BSM150GAL120DN2
BSM200GAL120DN2
BSM100GAR120DN2
BSM150GAR120DN2
BSM200GAR120DN2
5 Ohm
5 Ohm
5 Ohm
5 Ohm
5 Ohm
5 Ohm
5 Ohm
5 Ohm
2,5 Ohm
2,5 Ohm
2,5 Ohm
1 Ohm
2,5 Ohm
2,5 Ohm
2,5 Ohm
2,5 Ohm
2,5 Ohm
2,5 Ohm
BSM300GAR120DLC
BSM150GAL120DLC
BSM200GAL120DLC
BSM300GAL120DLC
1 Ohm
2,5 Ohm
2,5 Ohm
1 Ohm
FF400R12KF4
FF600R12KF4
FF800R12KF4
FF400R12KL4C
FF600R12KL4C
FF800R12KL4C
0,62 Ohm
0,62 Ohm
0,62 Ohm
0,62 Ohm
0,62 Ohm
0,62 Ohm
FZ800R12KS4
FZ800R12KF4
FZ1050R12KF4
0,56 Ohm
0,56 Ohm
0,61 Ohm
preliminary
BSM200GB120DLC
BSM300GB120DLC
FF100R12KS4
FF150R12KS4
FF200R12KS4
BSM200GA120DN2
BSM200GA120DN2S
BSM300GA120DN2
BSM300GA120DN2S
BSM300GA120DN2E3166
BSM400GA120DN2
BSM400GA120DN2S
BSM200GA120DLC
BSM200GA120DLCS
BSM300GA120DLC
BSM300GA120DLCS
BSM400GA120DLC
BSM400GA120DLCS
BSM600GA120DLC
BSM600GA120DLCS
FZ800R12KL4C
FZ1200R12KL4C
FZ1600R12KL4C
FZ1800R12KL4C
FZ2400R12KL4C
2,5 Ohm
1 Ohm
2,5 Ohm
2,5 Ohm
2,5 Ohm
1,25 Ohm
1,25 Ohm
1,25 Ohm
1,25 Ohm
1,25 Ohm
1,25 Ohm
1,25 Ohm
1,25 Ohm
1,25 Ohm
1,25 Ohm
1,25 Ohm
1,25 Ohm
1,25 Ohm
0.5 Ohm
0.5 Ohm
0,31 Ohm
0,31 Ohm
0,31 Ohm
0,21 Ohm
0,21 Ohm
FS300R12KF4
FS400R12KF4
FD400R12KF4
FD600R12KF4
F4-400R12KF4
F4-400R12KS4_B2
1,25 Ohm
FZ1200R17KF6C_B2
FZ1600R17KF6_B2
FZ1600R17KF6C_B2
FZ1800R17KF6_B2
FZ2400R17KF6C_B2
FD600R17KF6_B2
FD600R17KF6C_B2
FD800R17KF6_B2
0,76 Ohm
0,62 Ohm
0,62 Ohm
0,67 Ohm
0,67 Ohm
1,53 Ohm
1,53 Ohm
0,76 Ohm
1,25 Ohm
0,63 Ohm
1,25 Ohm
1,25 Ohm
Table 4.2.3 RG intern 1200V Modul
FF400R17KF6C_B2
FF600R17KF6_B2
FF800R17KF6C_B2
FZ800R17KF6C_B2
FZ1200R17KF6_B2
1,53 Ohm
1,53 Ohm
1,25 Ohm
0,76 Ohm
0,76 Ohm
Table 4.2.4 RG intern 1700V Modul
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Page 31
Technical Information
EiceDRIVER™ 2ED300C17-S
preliminary
4.3 Type designation
EiceDRIVER™
For example:
eupec IGBT controlled efficiency DRIVER
2ED300C17-S
Isolation class:
F = funktion isolation
S = safety isolation
ST= safety isolation/ Traction
Voltage class:
06 = 600V
12 = 1200V
17 = 1700V und 1200V
33 = 3300V
65 = 6500V
Driver type:
C = Driver core with DC/DC
E = Evaluation board
I = Driver IC (Coreless Transformer)
L = Driver IC (Level shifter)
Maximum output current:
For example
004 = 0.4 A
020 = 2.0 A
300 = 30.0 A
eupec IGBT driver
Driver channels
1 = single driver
2 = halfbride driver
6 = SixPACK driver
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Page 32