Evaluation Adapter Board for 62mm Half Bridge IGBT Modules

Application Note AN 2012-08
V1.0 December 2012
AN2012-08 Evaluation Adapter Board
for 62mm Half Bridge IGBT Modules
Application Note AN 2012-08
Evaluation Adapter Board for
62mm half bridge IGBT Modules
V1.0 December 2012
Edition 2011-06-01
Published by
Infineon Technologies AG
59568 Warstein, Germany
© Infineon Technologies AG 2011.
All Rights Reserved.
Attention please!
THE INFORMATION GIVEN IN THIS APPLICATION NOTE IS GIVEN AS A HINT FOR THE IMPLEMENTATION OF THE INFINEON TECHNOLOGIES COMPONENT ONLY AND SHALL NOT BE REGARDED
AS ANY DESCRIPTION OR WARRANTY OF A CERTAIN FUNCTIONALITY, CONDITION OR QUALITY
OF THE INFINEON TECHNOLOGIES COMPONENT. THE RECIPIENT OF THIS APPLICATION NOTE
MUST VERIFY ANY FUNCTION DESCRIBED HEREIN IN THE REAL APPLICATION. INFINEON
TECHNOLOGIES HEREBY DISCLAIMS ANY AND ALL WARRANTIES AND LIABILITIES OF ANY KIND
(INCLUDING WITHOUT LIMITATION WARRANTIES OF NON-INFRINGEMENT OF INTELLECTUAL
PROPERTY RIGHTS OF ANY THIRD PARTY) WITH RESPECT TO ANY AND ALL INFORMATION
GIVEN IN THIS APPLICATION NOTE.
Information
For further information on technology, delivery terms and conditions and prices please contact your
nearest Infineon Technologies Office (www.infineon.com).
Warnings
Due to technical requirements components may contain dangerous substances. For information on the
types in question please contact your nearest Infineon Technologies Office. Infineon Technologies
Components may only be used in life-support devices or systems with the express written approval of
Infineon Technologies, if a failure of such components can reasonably be expected to cause the failure of
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support devices or systems are intended to be implanted in the human body, or to support and/or maintain
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other persons may be endangered.
AN 2012-08
Revision History: date (2012-12-12), V1.0
Previous Version: none
Subjects: none
Author: Alain Siani
We Listen to Your Comments
Any information within this document that you feel is wrong, unclear or missing at all? Your feedback will
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2
Application Note AN 2012-08
Evaluation Adapter Board for
62mm half bridge IGBT Modules
V1.0 December 2012
1 Introduction .................................................................................................................................................. 4
1.1
Part Number explanation ................................................................................................................... 4
2 Design features ............................................................................................................................................ 5
2.1
Main features ..................................................................................................................................... 5
2.2
Key Data ............................................................................................................................................ 5
2.3
Mechanical dimensions ...................................................................................................................... 6
2.4
Pin assignment .................................................................................................................................. 6
3 Functionality on board ................................................................................................................................ 7
3.1
Gate resistors ..................................................................................................................................... 8
3.2
Gate signal amplifier .......................................................................................................................... 8
3.3
VCE monitoring for short circuit detection ........................................................................................... 8
3.4
Active voltage clamping – boosted version........................................................................................ 9
3.5
Maximum switching frequency ........................................................................................................... 9
4 Paralleling...................................................................................................................................................10
4.1
Static current imbalance ..................................................................................................................10
4.2
Dynamic current imbalance .............................................................................................................10
4.3
Paralleling with MA070E12/17_EVAL ..............................................................................................11
5 Schematics and Layouts ..........................................................................................................................12
5.1
Schematics.......................................................................................................................................12
5.2
Layouts .............................................................................................................................................14
6 Bill of Material ............................................................................................................................................15
7 How to order the Evaluation Adapter Board ...........................................................................................17
8 Literature ....................................................................................................................................................17
The board described is an evaluation board dedicated for laboratory
environment only. It operates at high voltages. This board must be operated
by qualified and skilled personnel familiar with all applicable safety standards.
3
Application Note AN 2012-08
Evaluation Adapter Board for
62mm half bridge IGBT Modules
V1.0 December 2012
1 Introduction
The MA070E12/17_EVAL module adapter board, shown in Figure 1, offers reliable connection between
driver and 62mm IGBT modules. Handling of the 62mm modules are described in [7] and [8]. The
MA070E12/17_EVAL board is designed to work with all 62mm half bridge IGBT module types respectively in
1200V and 1700V classes. The MA070E12/17_EVAL adapter board is appropriate to be used in combination
with the flexible driver Kit 2ED300E17-SFO evaluation adapter board and 2ED300C17-S /-ST
EiceDRIVER™, both in single as well as in parallel configuration. The flexible driver kit allows for a
paralleling of up to three IGBT modules. Each IGBT module within the parallel configuration needs one
MA070E12/17_EVAL board as depicted in Figure 1.
The board is available from Infineon in small quantities. The properties of this board are described in the
design feature chapter of this document, whereas the remaining paragraphs provide information to enable
the customers to copy, modify and qualify the design for production, according to their own specific
requirements.
Environmental conditions were considered in the design of the MA070E12/17_EVAL. Components qualified
for a lead-free reflow soldering process were selected. The design was tested as described in this document
but not qualified regarding manufacturing and operation within the whole operating temperature range or
lifetime.
The boards provided by Infineon are subject to functional testing only.
Due to their purpose, evaluation boards are not subject to the same procedures regarding Returned Material
Analysis (RMA), Process Change Notification (PCN) and Product Discontinuation (PD) as regular products.
See Legal Disclaimer and Warnings for further restrictions on Infineon’s warranty and liability.
Figure 1: 62mm IGBT module FF300R17KE3 equipped with MA070E12/17_EVAL Evaluation Adapter
board
1.1
Part Number explanation
4
Application Note AN 2012-08
Evaluation Adapter Board for
62mm half bridge IGBT Modules
V1.0 December 2012
2 Design features
Electrical features of the evaluation board as well as mechanical dimensions including necessary interface
connections are presented in the following sections.
2.1
Main features
The MA070E12/17 module adapter board offers:

Dual channel IGBT driver in combination with 2ED300E17-SFO [5] and 2ED300C17-S /-ST
EiceDRIVER™
Electrically and mechanically suitable for 62mm IGBT module family
Different gate resistor values for turning-on and -off are possible
IGBTs are secured against temporary collector - emitter overvoltages during turn-off by Active Clamping
Desaturation output signals for short circuit monitoring
All components, except connectors, are surface mounted devices with lead-free 260°C
soldering profile
The PCB is designed to fulfil the requirements of IEC61800-5-1, pollution degree 2, overvoltage
category III






Useful features in case the MA070E12/17_EVAL is not used with 2ED300E17-SFO adapter board and
2ED300C17-S /-ST EiceDRIVER™:
 Can be used with max. ±20V isolated power supply. Due to IGBT short circuit performance a value of
max. +16V is suggested.
 Asymmetric power supply is also allowed, e.g. +16 V and -8 V
 Input PWM positive and negative voltage pulse level should be selected according to the actual power
supply voltage level. Maximum +16 V and minimum -8 V at +16 V / -8 V power supply or maximum +15 V
and minimum -15 V at +15 V / -15 V power supply.
2.2
Key Data
General key data and characteristic values are given in Table 1. These are typical values, measured at an
ambient temperature of Tamb = 25 °C.
Table 1: Electrical Parameters
Parameter
Description
UDC
max. DC voltage supply
IG
maximum output continuous current
PDC/DC
max DC/DC output power per channel
Top
operating temperature
Tsto
storage temperature
1
2
1
2
Value
Unit
±20
V
±8
A
4
W
-40…+85
°C
-40…+85
°C
Only if MA070E12/17_EVAL is used in combination with 2ED300E17-SFO adapter board and 2ED300C17-S EiceDRIVER™
Max. tolerable ambient temperature strictly depends on MA070E12/17_EVAL load conditions.
5
Application Note AN 2012-08
Evaluation Adapter Board for
62mm half bridge IGBT Modules
2.3
V1.0 December 2012
Mechanical dimensions
The dimensions of the MA070E12/17 evaluation board are given in Figure 2.
Figure 2: Mechanical dimension of MA070E12/17_EVAL
2.4
Pin assignment
After the module adapter has been mounted to the 62mm module, all external electrical signals listed in
Table 2 should be applied to connector X1 and X2 as shown in Figure 3. If the MA070E12/17_EVAL is used
in combination with the 2ED300E17-SFO, the necessary connections to the module adapter board are also
depicted in Figure 3. In this case, the Sense-Signal of the 2ED300S17-S driver is used instead of the OutSignal, making the internal booster of the 2ED300C17 redundant. The control signals required for module
driving should be connected to the input interface of the 2ED300E17-SFO as described in AN2007-05.
Figure 3: Connection between 2ED300E17-SFO and MA070E12/17
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Application Note AN 2012-08
Evaluation Adapter Board for
62mm half bridge IGBT Modules
V1.0 December 2012
Table 2: Pin assignment of the connectors X1 and X2 MA070E12/17_EVAL
Pin
Label
Function
X2.5
VA+
Insulated DC/DC positive voltage supply
X2.4
COM A
Auxiliary emitter
X2.3
VA-
Insulated DC/DC negative voltage supply
X2.2
VGE A
Gate-emitter signal source
X2.1
VCESATA
Desaturation voltage monitoring output
X1.5
VB+
Insulated DC/DC positive voltage supply
X1.4
COM B
Auxiliary emitter
X1.3
VB-
Insulated DC/DC negative voltage supply
X1.2
VGE B
Gate-emitter signal source
X1.1
VCESATB
Desaturation voltage monitoring output
high side
low side
3 Functionality on board
The MA070E12/17_EVAL basically supports already existing IGBT drivers in half-bridge configuration and
provides additional functions separately for high- and low-side IGBT:
 Gate signal amplifier / emitter follower - booster
 VCE monitoring for short circuit detection
 Active voltage clamping
Figure 4 depicts the MA070E12/17_EVAL with functional blocks and shows their physical location.
Figure 4: Functional blocks of the MA070E12/17_EVAL
7
Application Note AN 2012-08
Evaluation Adapter Board for
62mm half bridge IGBT Modules
3.1
V1.0 December 2012
Gate resistors
The MA070E12/17_EVAL are assembled and delivered as shown on Figure 4, but without gate resistors.
Proper gate resistors should be soldered by the customer according to the chosen module. The datasheet
value of the gate resistor according to the selected module may be used as a starting point, but lower values
are permissible as long as the datasheet value of dIC/dt is not exceeded and the module is able to switch
without oscillations. The switching losses will also vary with application parameters. For more information on
these topics please refer to [1] and [2].
To avoid degradation of the gate resistors, repetitive pulse power rated resistors should be selected.
Further hints about the selection of pulse resistors are available on the web site of the manufacturers.
If it is intended to use different values for Rgon and Rgoff assembly of the diodes D_T1, D_T2, D_B1, D_B2 is
mandatory. In Figure 5, the locations of these diodes are shown. Rgon and Rgoff are the equivalent turn-on and
turn-off resistors for the paralleling of R_GT3 and R_GT4 respectively R_GT1 and R_GT2 as can be seen in
Figure 11.
Figure 5: The MA070E12/17_EVAL location of optional diodes
Dead time has to be adjusted according to the chosen module, driver supply voltages and gate resistors. For
details refer to [3].
3.2
Gate signal amplifier
During the turn-on and turn-off of the IGBT, a high peak of gate current must be delivered from the driver.
Usually there is no technical problem when one module is driven. If one IGBT driver is used for modules
connected in parallel, the signal amplifier must deliver the cumulated gate current. This setup suffers from
multiple drawbacks as described in [4] and [5]. To overcome the limitations of the single driver approach in
paralleling, each IGBT module should be equipped with one adapter board. The use of MA070E12/17_EVAL
boards offers a dedicated solution to fulfill the high peak current demand of each paralleled IGBT module. In
this approach all modules are controlled by one PWM input signal, but driven by a proper adequate power
source, also eliminating circulation current among paralleled modules.
3.3
VCE monitoring for short circuit detection
When the IGBT conducts a current several times higher than the nominal current, the IGBT desaturates and
the collector-emitter voltage increases. This behaviour can be practically used for short circuit detection and
protection of the IGBT. The short circuit duration time for Infineon 1200V and 1700V IGBT modules must not
exceed 10µs. During this time the short circuit should be detected and the IGBT switched off without
exceeding VCES.
If the MA070E12/17_EVAL board is used in combination with 2ED300E17-SFO, the soft shut down resistors
RSSD must be chosen correctly in order to ensure proper short circuit protection. Chapter 3.5 of AN2007-05
describes the procedure in detail.
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Application Note AN 2012-08
Evaluation Adapter Board for
62mm half bridge IGBT Modules
3.4
V1.0 December 2012
Active voltage clamping – boosted version
Active clamping is a technique which keeps transient overvoltages below the critical limits when the IGBT
turns off. The standard approach for active clamping is to use a chain of avalanche diodes connected
between the auxiliary collector and the gate of an IGBT module. When the collector-emitter voltage exceeds
the diodes breakdown voltage, the diodes current sums up with the current from the driver output. Due to the
now increased gate-emitter voltage the transistor is held in an active mode and the turning-off process is
interrupted. The dIC/dt slows down which results in a limited voltage overshoot. Avalanche diodes conduct
high peak currents during the time period in which the clamping is actively limiting the overvoltage.
Overvoltage protection of the MA070E12/17_EVAL is based on active clamping as described above. The
clamping diodes are connected directly to the IGBT’s gate as well as to the input of the amplifier located on
the MA070E12/17_EVAL. Therefore, the major amount of current for recharging the gate is derived from the
gate driver’s power supply instead of via the clamping diodes. This technique offers the advantage to use
TVS diodes with lower pulse power. The two versions of the evaluation adapter boards for 1200V and 1700V
are sharing the same layout. The difference between both is the choice of the TVS diodes for each voltage
class.
Active clamping is intended as a means of overvoltage protection in case of an over-current and short-circuit
turn-off. If active clamping operates repetitively, e.g. because of extraordinary high DC-link stray inductance
or excessive DC-link voltage, a significant increase in switching losses might damage the module.
3.5
Maximum switching frequency
The switching frequency of the adapter board is limited either by the maximum output power of the driver
power supply or by the maximum temperature of the PCB due to the power losses in the external gate
resistors. These power losses in the gate resistors depend on the IGBT gate charge, gate voltage magnitude
and on the switching frequency of the IGBT. Due to the power losses in the external gate resistors, heat will
be generated, which leads to an increase of the PCB temperature in the neighborhood of these resistors.
This temperature must not be higher than the maximum working temperature of the PCB, i.e. 105°C for a
standard FR4 material.
The calculation of the power losses in the gate resistors can be done by utilizing equation (1):
Pdis  P( REXT )  P( RINT )  Vout  f s  QG
(1)
where:
Pdis
= dissipated power
P(REXT) = dissipated power of the external gate resistors
P(RINT) = dissipated power of the IGBT module internal gate resistor
ΔVout = voltage magnitude at the driver output
fs
= switching frequency
QG
= IGBT gate charge for the given gate voltage range
The ratio of the losses dissipated internally P(RINT) and externally P(REXT) corresponds directly to the ratio of
the mentioned RINT and REXT resistors.
Due to the PCB temperature criteria, the power dissipated in the external gate resistors P(REXT) has to be
considered for the thermal design.
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Application Note AN 2012-08
Evaluation Adapter Board for
62mm half bridge IGBT Modules
V1.0 December 2012
Figure 6 illustrates the PCB board temperature around the gate resistors depending on the switching
frequency and defined conditions: Tamb = 60°C, VGE = -15V/+15V. Used at a switching frequency of 20kHz,
the board temperature remains clearly below the critical limit of 105°C for a standard FR4 PCB material.
Figure 6: board temperature around the gate resistors of MA070E12/17_EVAL board in conjunction
with FF300R17KE4 IGBT module
4 Paralleling
In contrast to the operation of one single IGBT, the switching of paralleled IGBT modules on the same
operation point is not trivial. This can be explained by the fact that the IGBTs have a certain variation in their
characteristics. A direct consequence of this is a slight current imbalance between the IGBTs. The biggest
challenge is to minimize the deviation of the leg current to achieve highly efficient systems and an improved
reliability.
Two main factors have a dominant role in the current maldistribution:
- the difference between the impedance of each leg of the paralleled setup
- the difference in the output voltages of the individual leg of the paralleled setup
4.1
Static current imbalance
The static current imbalance can be caused by the variation of
- the collector-emitter voltage of each leg of the paralleled setup
- the resistance of the main current path
4.2
Dynamic current imbalance
The dynamic current imbalance can be caused by the variation of
- the transmission characteristics caused by the different VGEth of each IGBT
- the impedance of the main current path
- the stray inductance of the internal and external commutation path of the IGBT module
- the IGBT driver output resistance in the paralleled legs
- the transfer characteristic IC = f(VGE)
10
Application Note AN 2012-08
Evaluation Adapter Board for
62mm half bridge IGBT Modules
4.3
V1.0 December 2012
Paralleling with MA070E12/17_EVAL
The MA070E12/17_EVAL was primarily designed to work with the evaluation driver board
2ED300E17-SFO_EVAL which allows the parallel connection of up to three modules as represented in
Figure 7. It must be noticed that soft shut down resistors RSSD in every case should be selected according to
AN2007-05 chapter 3.5.
Figure 7: Principle of parallel connection of 3 MA070E12/17_EVAL with 2ED300E17-SFO_Eval
The wires to connect the driver to the adapter boards should have the same length to avoid differences in
signal run time between the gates of the three legs. Star connection of the IGBTs reduces the cross flow in
the auxiliary emitter paths during the switching sequence. The MA070E12/17_EVAL board is equipped with
4R7 resistors in the auxiliary emitter path and -15V/+15V power supply lines to reduce the current cross flow
between the units of the paralleled circuits. Figure 8 shows the switching behavior of three FF300R17KE4
modules in parallel, driven by 2ED300E17-SFO_Eval and 2ED300C17-S /-ST EiceDRIVER™.
a)
b)
Figure 8: Current distribution on the AC terminals of 3 parallel FF300R17KE4 modules
a) Turn-on
b) Turn-off
The turn-on and turn-off were measured with a gate resistance Rgon = Rgoff = 1R5 and at Tamb = 25°C.
11
Application Note AN 2012-08
Evaluation Adapter Board for
62mm half bridge IGBT Modules
V1.0 December 2012
5 Schematics and Layouts
To meet individual customer requirements and make the evaluation adapter board for the 62mm IGBT
module a basis for development or modification, all necessary technical data like schematic, layout and
components are included in this chapter.
5.1
Schematics
Figure 9 depicts the driver circuit of the high side IGBT.
Figure 9: MA070E12/17_EVAL booster high side
Figure 10 illustrates the driver circuit of the low side IGBT.
Figure 10: MA070E12/17_EVAL booster low side
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Application Note AN 2012-08
Evaluation Adapter Board for
62mm half bridge IGBT Modules
V1.0 December 2012
Figure 11 shows the gate resistors and active clamping circuit of high and low side IGBTs.
Figure 11: MA070E12/17_EVAL gate resistor and active clamping high and low side
Figure 12 details the pin assignment of the high and low side of MA070E12/17_EVAL’s connectors.
Figure 12: MA070E12/17_EVAL connectors
13
Application Note AN 2012-08
Evaluation Adapter Board for
62mm half bridge IGBT Modules
5.2
V1.0 December 2012
Layouts
Figures 13, 14 and 15 give an overview about the layout of the MA070E12/17_EVAL board.
Figure 13: MA070E12/17_EVAL – assembly drawing
Figure 14: MA070E12/17_EVAL – Top layer
Figure 15: MA070E12/17_EVAL – Bottom layer
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Application Note AN 2012-08
Evaluation Adapter Board for
62mm half bridge IGBT Modules
V1.0 December 2012
6 Bill of Material
The bill of material includes a part list as well as assembly notes.
The tolerances for resistors should be less or equal to ±1 %, for capacitors of the type C0G less or equal to
±5 % and for capacitors of the type X7R less or equal to ±10 %.
The basic circuit and layout for MA070E12 and MA070E17 are all the same. The only difference is the type
of transil diodes used for active clamping as can be seen in the bill of materials. Gate resistors should be
assembled according to the hints given in Table 3.
Table 3: Assembly Active clamping diodes on the MA070E12/17_EVAL board
Board Names
Types of assembled
Assembled diodes
MA070E12_EVAL
diodes
D1.1C, D1.2C, D1.3C, D1.4C
D2.1C, D2.2C, D2.3C, D2.4C
SMJC188A
D1.1C, D1.2C, D1.3C
MA070E17_EVAL
D2.1C, D2.2C, D2.3C (D1.4C and D2.4C are
1.5SMC440A
bypassed by 0R resistors or wire)
Table 4: Bill of Material for MA070E12_EVAL adapter board
Type
Value / Type
Package
QTY
Name Part
Recommanded
Assembly
Manufacturer
Resistor
12R
R0805
4
R_B1, R_B2, R_T1, R_T2,
no special
yes
Resistor
1k
R0805
2
R_DB, RD_T
no special
yes
Resistor
4R7
M1206
6
R_B+, R_B-, R_T+,R_T-, R_B_GND,
no special
yes
no special
yes
R_T_GND
Resistor
12R
R0603
4
R_BC1, R_BC2,
R_TC1, R_TC2
Resistor
10k
R0805
2
R_T, R_B
no special
yes
Semiconductor
BAT165
SOD323
2
D1, D2
Infineon
yes
Semiconductor
STPS1L40
SMB
2
D1, D2
STM
yes
Semiconductor
ES1D
DO214AC
8
D_B1, D_B2, D_BB, D_BB1, D_T1,
Vishay
yes
Vishay
yes
D_T2, D_BT, D_BT1
Semiconductor
1.5SMC188 A
SMC
8
D1.1C, D1.2C, D1.3C, D1.4C
Semiconductor
STTH112U
SOD6
4
D_DB, D_DB1, D_DT, D_DT1
STM
yes
Resistor
1R
R1206
2
R_BB, R_BT
no special
yes
R esistor*
variable
R2010
8
R_GB1, R_GB2, R_GB3, R_GB4,
special pulse
No
R_GT1, R_GT2, R_GT3, R_GT4
resistor
2
CB, CT
TE-connectivity
yes
4
T_PT1, T_PT2,
Zetex
yes
D2.1C, D2.2C, D2.3C, D2.4C
Connector
ST2.8
Semiconductor
ZXTN2010Z
AMP
0-0735187-2
SOT89
T_PB1, T_PB2,
15
Application Note AN 2012-08
Evaluation Adapter Board for
62mm half bridge IGBT Modules
Type
Value / Type
Package
V1.0 December 2012
QTY
Name Part
Recommanded
Assembly
Manufacturer
Semiconductor
ZXTP2012Z
SOT89
4
T_NT1, T_NT2,
Zetex
yes
Molex
yes
Murata
yes
T_NB1, T_NB2
Connector
6410-5A
6410-5A
2
X1, X2
C_B1, C_B2, C_B3, C_B4, C_B5,
C_B6, C_B7, C_B8, C_T1, C_T2,
Capacitor
4µ7
C1206
16
C_T3, C_T4, C_T5, C_T6, C_T7,
C_T8,
Resistor
12R
R0805
4
R_B1, R_B2, R_T1, R_T2
no special
yes
Resistor
1k
R0805
2
R_DB, RD_T
no special
yes
*Pulse power rated types
Table 5: Bill of Material for MA070E17_EVAL adapter board
Type
Value / Type
Package
QTY
Name Part
Recommanded
Assembly
Manufacturer
resistor
12R
R0805
4
R_B1, R_B2, R_T1, R_T2,
no special
yes
Resistor
1k
R0805
2
R_DB, RD_T
no special
yes
Resistor
4R7
M1206
6
R_B+, R_B-, R_T+,R_T-, R_B_GND,
no special
yes
no special
yes
R_T_GND
Resistor
12R
R0603
4
R_BC1, R_BC2,
R_TC1, R_TC2
Resistor
10k
R0805
2
R_T, R_B
no special
yes
Semiconductor
BAT165
SOD323
2
D1, D2
Infineon
yes
Semiconductor
STPS1L40
SMB
2
D1, D2
STM
yes
Semiconductor
ES1D
DO214AC
8
D_B1, D_B2, D_BB, D_BB1, D_T1,
Vishay
yes
Vishay
yes
Vishay
bypassed by
D_T2, D_BT, D_BT1
Semiconductor
1.5SMC440 A
SMC
6
Semiconductor
1.5SMC188 A
SMC
2
D1.1C, D1.2C, D1.3C,
D2.1C, D2.2C, D2.3C
D1.4C, D2.4C
0R resistor (i.e.
2512 Package)
Semiconductor
STTH112U
SOD6
4
D_DB, D_DB1, D_DT, D_DT1
STM
yes
Resistor
1R
R1206
2
R_BB, R_BT
no special
yes
Resistor*
variable
R2010
8
R_GB1, R_GB2, R_GB3, R_GB4,
special pulse
No
R_GT1, R_GT2, R_GT3, R_GT4
resistor
2
CB, CT
TE-connectivity
yes
T_PT1, T_PT2,
Zetex
yes
Zetex
yes
Connector
ST2.8
AMP
0-0735187-2
Semiconductor
ZXTN2010Z
SOT89
4
Semiconductor
ZXTP2012Z
SOT89
4
T_PB1, T_PB2,
T_NT1, T_NT2,
T_NB1, T_NB2
16
Application Note AN 2012-08
Evaluation Adapter Board for
62mm half bridge IGBT Modules
Type
Value / Type
Package
V1.0 December 2012
QTY
Name Part
Recommanded
Assembly
Manufacturer
Connector
6410-5A
6410-5A
2
X1, X2
Molex
yes
Murata
yes
C_B1, C_B2, C_B3, C_B4, C_B5,
C_B6, C_B7, C_B8, C_T1, C_T2,
Capacitor
4µ7
C1206
16
C_T3, C_T4, C_T5, C_T6, C_T7,
C_T8,
Resistor
12R
R0805
4
R_B1, R_B2, R_T1, R_T2
no special
yes
Resistor
1k
R0805
2
R_DB, RD_T
no special
yes
*Pulse power rated types
7 How to order the Evaluation Adapter Board
Every evaluation board has its own IFX order number and can be ordered via your Infineon sales partner.
Information can also be found at the Infineon Web Page: www.infineon.com
CAD-data for the board described here are available on request. The use of this data is subjected to the
disclaimer given in this AN. Please contact: [email protected]
IFX order number for MA070E12_EVAL:
IFX order number for MA070E17_EVAL:
IFX order number for 2ED300E17-SFO:
IFX order number for 2ED300C17-S:
IFX order number for 2ED300C17-ST:
SP001071992
SP001071998
SP000355559
SP000359184
SP000359188
8 Literature
[1]
[2]
[3]
[4]
[5]
[6]
[7]
[8]
[9]
Infineon Technologies AG: AN2008-02, 2ED100E12-F2 - 6ED100E12-F2 - Evaluation Driver Board
for EconoDUAL™3 and EconoPACK+™ modules, V1.2, August 2009
Bäßler, M.; Ciliox A.; Kanschat P.: On the loss – softness trade-off: Are different chip versions
needed for softness improvement? PCIM Europe 2009, Nuremberg, May 2009
Infineon Technologies AG: AN2007-04, How to calculate and to minimize the dead time requirement
for IGBTs properly, V1.0, May 2007
Luniewski, P.; Jansen U.; Hornkamp M.: Dynamic voltage rise control –the most efficient way to
control turn-off switching behaviour of IGBT transistors, Pelincec 2005, Warsaw, October 2005
Luniewski, P.; Jansen. U.: Benefits of system oriented IGBT module design for high power inverters,
EPE 2007, Aalborg, September 2007
Infineon Technologies AG: AN2007-05, Evaluation Board for 2ED300C17-S/-ST IGBT driver, V1.1,
Februar 2008
Infineon Technologies AG: AN2012-05, 62mm Modules Application and Assembly Notes, V1.1,
September 2012
Infineon Technologies AG: AN2012-05, 62mm Module Anwendungs- und Montage Hinweise, V1.1,
September 2012
Infineon Technologies AG: AN2011-05, Industrial IGBT Modules Explanation of Technical
Information, V1.0 January 2012
17