SEMIKRON SKHI10

SKHI 10/12
Absolute Maximum Ratings
Symbol Conditions
)
)
) '
& & I!
, #
#,
# #
+/ + B ) #
B ) /
' #7 ' #
#
+#F@/
*
#
&#
# # #
+
#, #, /
# @ (.'9 +" @ 8*/
# &
# &
#
'
# #
#
#
6$8
8)#F
)*$
!
SEMIDRIVERTM
High Power IGBT Driver
Characteristics
Symbol Conditions
SKHI 10/12
)
'
)D
Features
!" # $%&'(
)*$ " )
+#, #-
)*$. " )./
*%'!0 +*%'/ #1
1
1,
)*$ .
# #
+ /
, #
+2 3 )/
$ , ! #
+0'4 /
# #
,
Typical Applications
5
, %6
#7 8,
# 1
96
1)
# < "B C*; )+/
)+/
+/'
+/'
+
/
)*$#
&(
&
&
, #
#,
, +#F@/
, #, + #/
#
+/ B ) B ) #
+0'4/ B ) B ) . #
#
. #
#
%#F # 5
,
. . ## . . ## $ . ## &
#
)*$ #
# #
'( #
# #
'?? #
*
6#, #, ###
).
Values
Units
=
) D ;3
)
)
E=
E
"
GB
8
8
)
7)!H
"B
";G
";G
J;A
. "B @@@ D =B
)
>
>
H*
C*
. "B @@@ D =B
C*
# < "BC*; min.
typ.
max.
Units
K;K
B;
;3/
J
B;A
)
8
8
";B
";K
)
)
3;A
;B
)
)
)
)
D B
.=
@ B
;K
;K
; "/
B;"K/
""3/
""3/
H
H
H
)
7>
>
>
"
?
This technical information specifies semiconductor devices but promises no
characteristics. No warranty or guarantee expressed or implied is made regarding
delivery, performance or suitability.
#
# # 2)
#
# %( #-
1, &*$ # **$
3)
%#
1
2 8:
; #1
"
4)
4 &*$ < = 7>; **$ < 33 ?:
@ A
1
22-08-2003 MHW
© by SEMIKRON
Block diagram SKHI10
ISOLATION
1
2
INPUT
LEVEL
SELECTOR
Vin
15V
4
J3
7
+15V
Vs
MONITOR
0V
10,11
1
Vs DC/DC
CONVERTER
4
OUTPUT
BUFFER
- 8V
0Ω
primary side
Rgon
J2
Gon
3
Goff
Rgoff
2
E
10
6
1
Rgoff
SC
SOFT
TURN-OFF
ERROR
MEMORY
Vs
CCE
8
3
Vs
8,9
RCE
5
ERROR
VCE
5
5V
3
+15V
9
INPUT
BUFFER
J1
RESET
VCE
MONITORING
2
1
IRgoff
secondary side
Fig.1 The numbers refer to the description on page 4, section B.
124
CCE
RCE
Output
Connector
14 13
Input
Connector
4.5
1
4x3.5
J2
Rgoff
0Ω
2
5
Rgon
Rgoff-SC
ERROR logic
J3
Input Level
IRgoff
3
2 66
1
J1
4.5
Input connector = 14 pin flat cable according to DIN 41651
Output connector = MOLEX 41791 Series (mates with 41695 crimp terminal housing and crimp terminals 7258)
Fig.2 Dimensions (in mm) and connections of the SKHI 10
© by SEMIKRON 22-08-2003
Driver Electronic – PCB Drivers
1939
SEMIDRIVERTM SKHI 10
SEMIDRIVERTM SKHI 10/17
High Power Single IGBT Driver
General
The intelligent single IGBT driver, SKHI10 respectively
SKHI 10/17 is a standard driver for all power IGBTs on
the market.
The high power output capability was designed to switch
high current modules or several paralleled IGBTs even for
high frequency applications. The output buffer has been
improved to make it possible to switch up to 400A IGBT
modules at frequencies up to 20kHz.
A new function has been added to the short circuit
protection circuitry (Soft Turn Off), this automatically
increases the IGBT turn off time and hence reduces the
DC voltage overvoltage spikes, enabling the use of higher
DC-bus voltages. This means an increase in the final
output power. An integrated DC/DC converter with high
galvanic isolation (4 kV) ensures that the user is
protected from the high voltage (secondary side).
The power supplies for the driver may be the same as
used in the control board (0/+15V) without the
requirement of isolation. All information that is transmitted
between input and output uses ferrite transformers,
resulting in high dv/dt immunity (75kV/µs).
The driver input stage is connected directly to the control
board output and due to different control board operating
voltages the SKHI10’s input circuit includes a user voltage
level selector (+15V or +5V).
In the following only the designation SKHI 10 is used.
This is valid for both driver versions. If something is to be
explained special to SKHI 10/17 it will be descriped by
marking SKHI 10/17.
A. Features and Configuration of the Driver
A short description is given below. For detailed
information, please refer to section B.
a) The SKHI10 has an INPUT LEVEL SELECTOR circuit
which is adusted by J1 for two different levels. It is
present for CMOS (15V) level, but can be changed by
the user to HCMOS (5V) level by solder bridging the
pads marked J1 together. For long input cables, we do
not recommend the 5V level due to possible
disturbances emitted by the power side.
b) The ERROR MEMORY blocks the transmission of all
turn-on signals to the IGBT if either a short circuit or
malfunction of VS is detected, and sends a signal to
the external control board through an open collector
transistor.
c) With a FERRITE TRANSFORMER the information
between primary and secondary may flow in both
directions and high levels of dv/dt and isolation are
obtained.
d) A high frequency DC/DC CONVERTER avoids the
requirement of external isolated power supplies to
obtain the necessary gate voltage. An isolated ferrite
transformer in half-bridge configuration supplies the
necessary power to the gate of the IGBT. With this
1940
Driver Electronic – PCB Drivers
feature, we can use the same power supply used in
the external control circuit, even if we are using more
than one SKHI10, e.g. in H-bridge configurations.
e) Short circuit protection is provided by measuring the
collector-emitter voltage with a VCE MONITORING
circuit. An additional circuit detects the short circuit
after a delay (determined by RCE,CCE) and decreases
the turn off speed (adjusted by Rgoff-SC) of the IGBT.
SOFT TURN-OFF under fault conditions is necessary
as it reduces the voltage overshoot and allows for a
faster turn off during normal operation.
f) The OUTPUT BUFFER is responsible for providing the
correct current to the gate of the IGBT. If these signals
do not have sufficient power, the IGBT will not switch
properly, and additional losses or even the destruction
of the IGBT may occur. According to the application
(switching frequency and gate charge of the IGBT) the
equivalent value of Rgon and the Rgoff must be matched
to the optimum value. This can be done by putting
additional parallel resistors Rgon, Rgoff with those
already on the board. If only one IGBT is to be used,
(instead of parallel connection) only one cable could
be connected between driver and gate by soldering
the two J2 areas together.
Fig.1 shows a simplified block diagram of the SKHI10
driver. Some preliminary remarks will help the
understanding:
• Regulated +15V must be present between pins 8,9 (Vs)
and 10,11 (⊥); an input signal (ON or OFF command to
the IGBTs) from the control system is supplied to pin 2
(Vin) where HIGH=ON and LOW=OFF.
• Pin 5 (VCE) at secondary side is normally connected to
the collector of the IGBT to monitor VCE, but for initial
tests without connecting the IGBT it must be connected
to pin 1 (E) to avoid ERROR signal and enable the
output signals to be measured.
• The RESET input must be connected to 0V to enable
the Vin signal. If it is left opened, the driver will be
blocked.
• To monitor the error signal, a pull-up resistor must be
provided between pin 3 (ERROR) and VS.
B. Description of the Circuit Block Diagram
(Fig. 1)
The circuit in Fig. 1 shows the input on the left and output
on the right (primary/secondary).
1. Input level circuit
This circuit was designed to accept two different logic
voltage levels. The standard level is +15V (factory
adjusted) intended for noisy environments or when long
connections (l > 50 cm) between the external control
circuit and SKHI10 are used, where noise immunity must
be considerate. For lower power, and short connections
between control and driver, the TTL-HCMOS level (+5V)
22-08-2003
© by SEMIKRON
can be selected by carefully soldering the small areas of
J1 together, specially useful for signals coming from µP
based controllers.
VIT- (Low)
min
typ
max
15 V
3,6 V
4,2 V
4,8 V
5V
0,50 V
0,65 V
0,80 V
3. Error memory and reset signal
Fig.3 Selecting J1 for 5V level (TTL)
The ERROR memory is triggered only by following
events:
When connecting the SKHI10 to a control board using
short connections no special attention needs to be taken
(Fig. 4a).
• short circuit of IGBTs
• VS-undervoltage
In case of short circuit, the VCE monitor sends a trigger
signal (fault signal) through the impulse transformer to a
FLIP-FLOP on the primary side giving the information to
an open-collector transistor (pin 3), which may be
connected to the external control circuit as ERROR
message in HIGH logic (or LOW if J3 is short-circuited). If
VS power supply falls below 13V for more than 0,5ms, the
same FLIP-FLOP is set and pin 3 is activated. For HIGH
logic (default), an external RC must be connected
preferentiatty in the control main board. In this way the
connection between main board and driver is also
checked.
Fig.4a Connecting the SKHI10 with short cable
If low-logic version is used (J3 short-circuited), an internal
pull-up resistor (internally connected to VS) is provided,
and the signal from more SKHI10s can be connected
together to perform an wired-or-circuit.
Fig.4b Conneeting the SKHI10 with long cable
Otherwise, if the length is 50cm or more (we suggest to
limit the cable length to about 1 meter), some care must
be taken. The TTL level should be avoided and CMOS/
15V is to be used instead; flat cable must have the pairs
of conductors twisted or be shielded to reduce EMI/RFI
susceptibility (Fig. 4b). If a shielded cable is used, it can
be connected to pin 1. It is coupled to 0V through a
resistor (0 Ω).
As the input impedance of the INPUT LEVEL
SELECTOR circuit is very high, an internal pull-down
resistor keeps the IGBT in OFF state in case the Vin
connection is interrupted or left non connected.
Fig.5 Driver status information ERROR, and RESET
The ERROR signal may be disabled either by
RESET=HIGH (pin4) or by switching the power supply
(VS) off. The width of the RESET pulse must be more
than 5µs, and in case of interrupted connection an
internal pull-up resistor will act.
FAULT
RESET
ERROR1)
Vin
2. Input buffer
no
0
0
enable
This circuit enables and amplifies the input signal Vin to
be transferred to the pulse transformer when RESET
(pin 4) is LOW and also prevents spurious signals being
transmitted to the secondary side.
no
1
0
disable
yes
0
1
disable
yes
1
0
disable
The following overview is showing the input treshold
voltages
VIT+ (High)
min
typ
max
15 V
9,5 V
11,0 V
12,5 V
5V
1,8 V
2,0 V
2,4 V
© by SEMIKRON 22-08-2003
1)
default logic (HIGH); for LOW logic the signals are
complementary
Table 1 ERROR signal truth table
The open-collector transistor (pin 3) may be connected
through a pull-up resistor to an extemal (intemal VS for the
‘‘low-logixc‘‘ version) vorltage supply +5V...+24V, limiting
the current to lsink ≤6mA.
Driver Electronic – PCB Drivers
1941
4. Power supply (Vs) monitor
The supply voltage VS is monitored. If it falls below 13V
an ERROR signal is generated and the turn-on pulses for
the IGB’s gate are blocked.
turn-off time” can be reduced by connecting a parallel
resistor Rgoff-SC (see Fig. 2) with those already on the
printed circuit board.
9. VCE monitoring
5. Pulse transformer
It transmits the turn-on and turn-off signals to the IGBT. In
the reverse direction the ERROR signal from the VCE
monitoring is transmitted via the same transformer. The
isolation is 4 kV.
6. DC/DC converter
In the primary side of the converter, a half-bridge inverter
transfers the necessary energy from VS to the secondary
of a ferrite transformer. In the secondary side, a full bridge
and filters convert the high frequency signal coming from
the primary to DC levels (+15V/- 8V) that are stabilised by
a voltage regulator circuit.
7. Output buffer
The output buffer is supplied by the +15V/- 8V from the
DC/DC converter. If the operation proceeds normally (no
fault), the on- and off-signal is transmitted to the gate of
an IGBT through Rgon and Rgoff. The output stage has a
MOSFET pair that is able to source/sink up to 8A peak
current to/from the gate improving the turn-on/off time of
the IGBT. Additionally, we can select IRgoff (see Fig. 2)
either to discharge the gate capacitance with a voltage
source (standard) or with a current source, specially
design for the 1700V IGBT series (it speeds up the
turn-off time of the IGBT). The present factory setting is
voltage source (IRgoff = 0Ω). Using the current source
IRgoff, Rgoff must be 0 Ω.
Volt
VCE
VCEref = f(RCE,CCE)
RCE=100KΩ
CCE=1nF
RCE=18KΩ
CCE=330pF
14
tmin1
To avoid a false failure indication when the IGBT just
starts to conduct (VCEsat value is still too high) some
decay time must be provided for the VCEref. As the VCE
signal is internally limited at 10V, the decay time of VCEref
must reach this level after VCE or a failure indication will
occur (see Fig.6, curve 1). A tmin is defined as function of
VCEstat and τ to find out the best choice for RCE and VCE
(see Fig.6, curve 2). The time the IGBT come to the 10V
(represented by a „“ in Fig. 6) depends on the IGBT
itself and Rgon used.
• RCE > 10KΩ
3
10
The VCEref is not static but a dynamic reference which has
an exponential shape starting at about 15V and
decreases to VCEstat (5V ≤ VCEstat ≤ 10V determinated by
RCE), with a time constant τ (0,5 µs ≤ τ ≤ 1ms controlled
by CCE). The VCEstat must be adjusted to remain above
VCEsat in normal operation (the IGBT is already in full
saturation).
The RCE and CCE values can be found from Fig. 7 by
taking the VCEstat and tmin as input values with following
remarks:
18
IGBT
turn-on
This circuit is responsible for short-circuit sensing. Due to
the direct measurement of VCEstat on the IGBT’s collector,
it blocks the output buffer (through the soft turn-off circuit)
in case of short-circuit and sends a signal to the ERROR
memory on the primary side. The recognition of which
VCE level must be considered as a short circuit event, is
adjusted by RCE and CCE (see Fig. 2), and it depends of
the IGBT used. Typical values RCE =18kΩ and CCE =330
pF for SKHI 10 are delivered from factory (Fig. 6, curve
2). Using SKHI 10/17 the driver will be delivered with RCE
= 36 kΩ and CCE = 470 pF from factory.
• CCE < 2,7nF
RCE=10KΩ
CCE=10pF
tmin2
2
6
1
VCEstat2
VCEstat1
VCEsat
Attention!: If this function is not used, for example during
the experimental phase, the VCE MONITORING must be
connected with the EMITTER output to avoid possible
fault indication and consequent gate signal blokking.
2
1µ
3µ
5µ
7µ
9µ
sec
Fig.6 VCEref waveform with parameters RCE, CCE
8. Soft turn-off
In case of short-circuit, a further circuit (SOFT
TURN-OFF) increases the resistance in series with Rgoff
and turns-off the IGBT at a lower speed. This produces a
smaller voltage spike (due LSTRAY x di/dt) above the DC
link by reducing the di/dt value. Because in short-circuit
conditions the Homogeneous IGBT’s peak current
increases up to 8 times the nominal current (up to 10
times with Epitaxial IGBT structures), and some stray
inductance is ever present in power circuits, it must fall to
zero in a longer time than at normal operation. This “soft
1942
Driver Electronic – PCB Drivers
10. Rgon, Rgoff
These two resistors are responsible for the switching
speed of each IGBT. As an IGBT has input capacitance
(varying during the switching time) which must be
charged and discharged, both resistors will dictate what
time must be taken to do this. The final value of
resistance is difficult to predict, because it depends on
many parameters, as follows:
• DC-link voltage
• stray inductance of the circuit
• switching frequency
• type of IGBT
22-08-2003
© by SEMIKRON
10
100
µsec
volts
CCE
1nF
10
470pF
330pF
220pF
100pF
1
VSTAT
t min
0.1
0
Fig.7a
20
40
80 RCE 100 k Ω
60
1
0
20
40
80 RCE 100 k
60
Ω
Fig.7b VCEstat as function of RCE
tmin as function of RCE and CCE
CONTROL BOARD
C. Operating Procedure
INPUT CONNECTOR
OUTPUT CONNECTOR
+15V
1. One IGBT connection
l < 50cm
To realize the correct switching and short-circuit
monitoring of one IGBT some additional external
components must be used (Fig.8).
The driver is delivered with four Rg resistors (43Ω). This
value can be reduced to use the driver with bigger
modules or higher frequencies/lower voltages, by putting
additional resistors in parallel to the existing ones.
The outputs Gon and Goff were previewed to connect the
driver with more than one IGBT (paralleling). In that case
we need both signals ON/OFF separately to connect
additional external resistors Rgon and Rgoff for each IGBT.
If only one IGBT is to be used, we suggest to connect
both points together through J2 (see Fig. 1 and 2). This
can be done by soldering the two small pads together,
which saves one external connection.
2
4
2K7Ω
CCE
Rgon
Rgoff
Rgoff-SC
IRgoff
5
RCE
3
J2
1
3
10,11
as short as
SKHI10
possible
control GND
Fig. 8 Preferred standard circuit
RGon
Ω
RGoff
Ω
CCE
pF
RCE
kW
IRgoff
Ω
SKM 200GAL173D
8,2
8,2
470
36
0
SKM 300GA173D
6,8
6,8
470
36
0
SKM 400GA173
5,6
5,6
470
36
0
SK-IGBT-Module
Table 2b 1700V IGBT@ DC-link< 1000V
Typical component values: *)
SK-IGBT-Module
*) Only starting values, for final optimization.
RGon
Ω
RGoff
Ω
CCE
pF
RCE
kW
IRgoff
Ω
SKM 75GAL123D
22
22
330
18
0
SKM 100GAL(R)123D
15
15
330
18
0
SKM 150GAL(R)123D
12
12
330
18
0
SKM 200GA(L/R)123D
10
10
330
18
0
SKM 300GA(L/R)123D
8,2
8,2
330
18
0
SKM 400GA123D
6,8
6,8
330
18
0
SKM 500GA123D
5,6
5,6
330
18
0
Table 2a 1200V IGBT@ DC-link< 700V
© by SEMIKRON 22-08-2003
The adjustment of RgoffSC (factory adjusted RgoffSC = 22 Ω)
should be done observing the overvoltages at the module
in case of short circuit. When having a low inductive
DC-link the module can be switched off faster.
The values shown should be considered as standard
values for a mechanical/electrical assembly, with
acceptable stray inductance level, using only one
IGBT per SKHI10 driver. The final optimized value can
be found only by measuring.
2. Paralleling IGBTs
The parallel connection is recommended only by using
IGBTs with homogeneous structure (IGHT), that have a
positive temperature coefficient resulting in a perfect
Driver Electronic – PCB Drivers
1943
Fig. 9 Preferred circuit for paralleled IGBT’s
current sharing without any external auxiliary element.
After all some care must be considered to reach an
optimized circuit and to obtain the total performance of
the IGBT (Fig. 9). The IGBTs must have independent
values of Rgon and Rgoff. An auxiliary emitter resistor Re as
well as an auxiliary collector resistor Rc must also be
used.
The external resistors Rgonx, Rgoffx, Rex and Rcx should be
mounted on an additional circuit board near the paralleled
modules, and the Rgon/Rgoff on the driver should be
changed to zero ohms.
The Rex assumes a value of 0,5Ω and its function is to
compensate the wiring resistance in the auxiliary emitters
what could make the emitter voltage against ground
unbalanced.
The Rcx assumes a value of 47 Ω and its function is to
create an average value of VCEsat in case of short circuit
for VCE monitoring.
The Mechanical assembly of the power circuit must be
symmetrical and low inductive.
The maximum recommended gate charge is 9,6 µC.
See als Fig.14.
Fig. 10 Input and output voltage propagation time
1944
Driver Electronic – PCB Drivers
Fig. 11 Output voltage (VGE) and output current (IG)
Fig. 12 Short-circuit and ERROR propagation time
worst-case (Vin with SC already present)
22-08-2003
© by SEMIKRON
D. Signal Waveforms
The following signal waveforms were measured under the
conditions below:
•
•
•
•
•
•
•
VS = 15 V
Tamb = 25 °C
load = SKM150GAL161D
RCE = 18 kΩ
CCE = 330 pF
UDC = 1200 V
IC = 100 A
If small IGBT modules are used, the frequency could
theoretically reach 100kHz. For bigger modules or even
paralleled modules, the maximum frequency must be
determinate (Fig. 14). QG is the total equivalent gate
charge connected to the output of the driver. The
maximum allowed value is limited (9,6µC), and depends
on the output internal capacitance connected to the
power supply (energy storage capacitance).
E. Application / Handling
1. The CMOS inputs of the driver are extremely sensitive
to overvoltage. Voltages higher than (VS + 0,3 V) or under
- 0,3 V may destroy these inputs.
All results are typical values if not otherwise specified.
The limit frequency of SKHI10 depends on the gate
charge connected in this output pins.
• To make sure that the control signals do not comprise
overvoltages exceeding the above values.
Vpeak=1360V
Vpeak=1280V
VCE =1200V
Therefore the following safety requirements are to be
observed:
• Protection against static discharges during handling.
As long as the hybrid driver is not completely
assembled the input terminals must be short circuited.
Persons working with CMOS devices should wear a
grounded bracelet. Any floor coverings must not be
chargeable. For transportation the input terminals must
be short circuited using, for example, conductive
rubber. Places of work must be grounded. The same
foam requirements apply to the IGBTs.
Isc=860A
100ohm
2. The connecting leads between the driver and the
power module must be as short as possible, and should
be twisted.
22ohm
V=200V/div H=1µs/div
V=250A/div
3. Any parasitic inductance should be minimized.
Overvoltages may be damped by C or RCD snubber
networks between the main terminals [3] = C1 (+) and [2]
= E2 (-) of the power module.
Fig.13 Effect of Rgoff-SC in short - circuit
4. When first operating a newly developed circuit, low
collector voltage and load current should be used in the
beginning. These values should be increased gradually,
observing the turn-off behavior of the free-wheeling
diodes and the turn-off voltage spikes across the IGBT by
means of an oscilloscope. Also the case temperature of
the power module should be monitored. When the circuit
works correctly, short circuit tests can be made, starting
again with low collector voltage.
100
kHz
80
not allowed area
60
f max
40
9,6µC
5. It is important to feed any ERROR back to the control
circuit to switch the equipment off immediately in such
events. Repeated turn-on of the IGBT into a short circuit,
with a frequency of several kHz, may destroy the device.
20
0
0
2
4
QG
6
8
µC
Fig.14 Maximum operating frequency x gate charge
© by SEMIKRON 22-08-2003
10
For further details ask SEMIKRON
Nr.11224040
Driver Electronic – PCB Drivers
1945