SKYPER32RUL_技术文档

SKYPER 32 R UL

Absolute Maximum Ratings

Symbol Conditions

Values

Unit

V_s

Supply voltage primary

Input signal voltage (HIGH)

Input signal voltage (LOW)

Output peak current

16

Vs + 0.3

GND - 0.3

15

V

V_iH

V_iL

V

Iout_PEAK

A

Iout_AVmaxOutput average current

50

mA

kHz

f_max

Max. switching frequency

50

SKYPER^®

Collector emitter voltage sense across

the IGBT

V_CE

1700

50

V

Rate of rise and fall of voltage

secondary to primary side

dv/dt

kV/µs

IGBT Driver Core

Isolation test voltage input - output

(AC, rms, 2s)

V_{isol IO}

V_isolPD

V_isol12

4000

1500

V

Partial discharge extinction voltage,

rms, Q_PD! 10pC

SKYPER 32 R UL

Preliminary Data

Isolation test voltage output 1 - output

2 (AC, rms, 2s)

Features

Minimum rating for external R_Gon

Minimum rating for external R_Goff

Max. rating for output charge per pulse

Operating temperature

R_{Gon min}

R_{Goff min}

Q_out/pulse

T_op

1.5

"

• UL recognized according UL 508C

• UL report reference E242581

• Two output channels

2.5

µC

°C

• Integrated potential free power supply

• Under voltage protection

-40 ... 85

T_stg

Storage temperature

• Drive interlock top / bottom

• Dynamic short cirucit protection

• Shut down input

Characteristics

• Failure management

Symbol Conditions

min.

typ.

max.

15.6

450

Unit

• IEC 60068-1 (climate) 40/085/56, no

condensation and no dripping water

permitted, non-corrosive, climate class

3K3 acc. EN60721

V_s

Supply voltage primary side

14.4

15

80

V

mA

V

I_SO

Supply current primary (no load)

Supply current primary side (max.)

Input signal voltage on / off

V_i

15 / 0

Typical Applications*

V_IT+

V_IT-

Input treshold voltage HIGH

Input threshold voltage (LOW)

12.3

V

• Driver for IGBT modules in bridge

circuits in industrial application

• DC bus voltage up to 1200V

4.6

V

Input resistance (switching/HALT

signal)

R_IN

10

k"

Footnotes

V_G(on)

V_G(off)

f_ASIC

Turn on output voltage

15

-7

V

V_CE:With external high voltage diode

Turn off output voltage

V

_isolIO/V_isol12: Isolation test is not performed

Asic system switching frequency

Input-output turn-on propagation time

Input-output turn-off propagation time

Error input-output propagation time

8

MHz

µs

as a series test at SEMIKRON and must be

performed by the user

t_d(on)IO

t_d(off)IO

t_d(err)

1.1

V

_isolPD: According to VDE 0110-20

_out/pulsecan be expanded to 6,3µQ with

µs

Q

5.4

7.9

4.3

µs

boost capacitors

t_pERRRESETError reset time

9

3

µs

Isolation coordination in compliance with

EN50178 PD2

t_TD

Top-Bot interlock dead time

µs

C_ps

w

Coupling capacitance prim sec

12

28

2.5

pF

g

10⁶h

Operating temperature is real ambient

temperature around the driver core

Degree of protection: IP00

MTBF

Mean Time Between Failure Ta = 40°C

This is an electrostatic discharge sensitive device (ESDS), international standard IEC

60747-1, Chapter IX

* The specifications of our components may not be considered as an assurance of component

characteristics. Components have to be tested for the respective application. Adjustments

may be necessary. The use of SEMIKRON products in life support appliances and systems is

subject to prior specification and written approval by SEMIKRON. We therefore strongly

recommend prior consultation of our personal.

Driver Core

Rev. 0 – 11.08.2010

1

SKYPER^®32 R UL

Technical Explanations

Revision

Status:

Prepared by:

00

Johannes Krapp

This Technical Explanation is valid for the following parts:

Related Documents:

title:

part number:

date code (YYWW):

L6100104

≥ 1030

Data Sheet SKYPER 32 R UL

SKYPER^®32 R UL

Content

Application and Handling Instructions .................................................................................................................... 2

Further application support..................................................................................................................................... 2

General Description................................................................................................................................................ 2

Features of SKYPER 32 R UL................................................................................................................................ 2

UL specified remarks.............................................................................................................................................. 3

Block diagram ......................................................................................................................................................... 3

Dimensions ............................................................................................................................................................. 3

PIN Array – Primary Side........................................................................................................................................ 4

PIN Array – Secondary Side................................................................................................................................... 5

Driver Performance................................................................................................................................................. 6

Insulation................................................................................................................................................................. 6

Isolation Test Voltage ............................................................................................................................................. 7

Auxiliary Power Supply........................................................................................................................................... 7

Under Voltage Protection of driver power supply (UVP) ........................................................................................ 8

Input Signals ........................................................................................................................................................... 8

Short Pulse Suppression (SPS) ............................................................................................................................. 8

Failure Management............................................................................................................................................... 9

Shut Down Input (SDI)............................................................................................................................................ 9

Dead Time generation (Interlock TOP / BOT) (DT).............................................................................................. 10

Dynamic Short Circuit Protection by V_CEsatmonitoring / de-saturation monitoring (DSCP).................................. 10

Adjustment of DSCP............................................................................................................................................. 11

High Voltage Diode for DSCP............................................................................................................................... 12

Gate resistors ....................................................................................................................................................... 12

External Boost Capacitors (BC)............................................................................................................................ 13

Application Example ............................................................................................................................................. 13

Mounting Notes..................................................................................................................................................... 14

Environmental Conditions..................................................................................................................................... 14

Marking ................................................................................................................................................................. 15

1

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SKYPER^®32 R UL

Please note:

Unless otherwise specified, all values in this technical explanation are typical values. Typical values are the average values expected in

large quantities and are provided for information purposes only. These values can and do vary in different applications. All operating

parameters should be validated by user’s technical experts for each application.

Application and Handling Instructions

ꢀ

Please provide for static discharge protection during handling. As long as the hybrid driver is not completely assembled,

the input terminals have to be short-circuited. Persons working with devices have to wear a grounded bracelet. Any

synthetic floor coverings must not be statically chargeable. Even during transportation the input terminals have to be

short-circuited using, for example, conductive rubber. Worktables have to be grounded. The same safety requirements

apply to MOSFET- and IGBT-modules.

ꢀ

Any parasitic inductances within the DC-link have to be minimised. Over-voltages may be absorbed by C- or RCD-

snubbers between main terminals for PLUS and MINUS of the power module.

When first operating a newly developed circuit, SEMIKRON recommends to apply low collector voltage and load current

in the beginning and to increase these values gradually, observing the turn-off behaviour of the free-wheeling diode and

the turn-off voltage spikes generated across the IGBT. An oscillographic control will be necessary. Additionally, the case

temperature of the module has to be monitored. When the circuit works correctly under rated operation conditions,

short-circuit testing may be done, starting again with low collector voltage.

ꢀ

It is important to feed any errors back to the control circuit and to switch off the device immediately in failure events.

Repeated turn-on of the IGBT into a short circuit with a high frequency may destroy the device.

The inputs of the hybrid driver are sensitive to over-voltage. Voltages higher than V_S+0,3V or below -0,3V may destroy

these inputs. Therefore, control signal over-voltages exceeding the above values have to be avoided.

The connecting leads between hybrid driver and the power module should be as short as possible (max. 20cm), the

driver leads should be twisted.

Further application support

Latest information is available at http://www.semikron.com. For design support please read the SEMIKRON Application

Manual Power Modules available at http://www.semikron.com.

General Description

The SKYPER 32 core constitutes an interface between IGBT modules and the controller. The driver is developed according

to the requirements of UL standard. This core is a half bridge driver. Basic functions for driving, potential separation and

protection are integrated in the driver. Thus it can be used to build up a driver solution for IGBT modules.

Features of SKYPER 32 R UL

SKYPER 32

ꢀ

Two output channels

Integrated potential free power supply for the secondary side

Short Pulse Suppression (SPS)

Under Voltage Protection (UVP)

Drive interlock (dead time) top / bottom (DT)

Dynamic Short Circuit Protection (DSCP) by V_CEmonitoring and direct

switch off

ꢀ

Shut Down Input (SDI)

Failure Management

Expandable by External Boost Capacitors (BC)

DC bus voltage up to 1200V

2

Rev 0 – 11.08.2010

SKYPER^®32 R UL

UL specified remarks

ꢀ

The equipment shall be installed in compliance with the mounting and spacing requirements of the end-use application.

SKYPER 32 shall be supplied by an isolated limited voltage / limited current source or a Class 2 source. The 15 A peak

rating is an instantaneous peak rating only.

ꢀ

These devices do not incorporate solid-state motor overload protection. The need for overload protection and over-

current protection devices shall be determined in the end-use product.

These devices have not been evaluated to over-voltage, over-current, and over-temperature control, and may need to

be subjected to the applicable end-product tests.

Temperature and tests shall be considered in the end use. Due to the limited current source, only the effect of heat

generating components in this device on adjacent components in the end product needs to be considered.

Connectors have not been evaluated field wiring; all connections are to be factory wired only.

Block diagram

Dimensions

Dimensions in mm (bottom view)

(top view)

0,2mm unless otherwise noted

3

Rev 0 – 11.08.2010

SKYPER^®32 R UL

PIN Array – Primary Side

Connectors

Connector X10 (RM2,54, 10pin)

0,25mm unless otherwise noted

Signal

Function

Specification

GND for power supply and GND for digital

signals

X10:01

PRIM_PWR_GND

GND for power supply and GND for digital

signals

X10:02

X10:03

PRIM_PWR_GND

LOW = NO ERROR; open collector output;

max. 30V / 15mA

(external pull up resistor necessary)

PRIM_nERROR_OUT

ERROR output

X10:04

X10:05

PRIM_nERROR_IN

PRIM_PWR_GND

ERROR input

5V logic; LOW active

GND for power supply and GND for digital

signals

GND for power supply and GND for digital

signals

X10:06

X10:07

PRIM_PWR_GND

PRIM_TOP_IN

Digital 15 V; 10 kOhm impedance;

LOW = TOP switch off;

HIGH = TOP switch on

Switching signal input (TOP switch)

Digital 15 V; 10 kOhm impedance;

LOW = BOT switch off;

HIGH = BOT switch on

X10:08

PRIM_BOT_IN

Switching signal input (BOTTOM switch)

X10:09

X10:10

PRIM_PWR_15P

Drive core power supply

Stabilised +15V 4%

4

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SKYPER^®32 R UL

PIN Array – Secondary Side

Connectors

Connector X100 / X200 (RM2,54, 10pin)

0,25mm unless otherwise noted

Signal

Function

Specification

X100:01

X100:02

SEC_TOP_VCE_CFG

SEC_TOP_VCE_IN

Input reference voltage adjustment

Input V_CEmonitoring

Output power supply for external buffer

capacitors

X100:03

X100:04

SEC_TOP_15P

Stabilised +15V

Output power supply for external buffer

capacitors

GND for power supply and GND for digital

signals

X100:05

X100:06

X100:07

X100:08

X100:09

SEC_TOP_GND

SEC_TOP_IGBT_ON

SEC_TOP_GND

Switch on signal TOP IGBT

GND for power supply and GND for digital

signals

SEC_TOP_IGBT_OFF

SEC_TOP_8N

Switch off signal TOP IGBT

Output power supply for external buffer

capacitors

Stabilised -7V

Output power supply for external buffer

capacitors

X100:10

SEC_TOP_8N

X200:01

X200:02

SEC_BOT_VCE_CFG

SEC_BOT_VCE_IN

Input reference voltage adjustment

Input V_CEmonitoring

Output power supply for external buffer

capacitors

X200:03

X200:04

SEC_BOT_15P

Stabilised +15V

Output power supply for external buffer

capacitors

GND for power supply and GND for digital

signals

X200:05

X200:06

X200:07

X200:08

X200:09

SEC_BOT_GND

SEC_BOT_IGBT_ON

SEC_BOT_GND

Switch on signal BOT IGBT

GND for power supply and GND for digital

signals

SEC_BOT_IGBT_OFF

SEC_BOT_8N

Switch off signal BOT IGBT

Output power supply for external buffer

capacitors

Stabilised -7V

Output power supply for external buffer

capacitors

X200:10

SEC_BOT_8N

5

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SKYPER^®32 R UL

Driver Performance

The driver is designed for application with half bridges or single modules and a maximum gate charge per pulse

< 2,5µC (< 6,3µC with external boost capacitors). The charge necessary to switch the IGBT is mainly depending on the

IGBT’s chip size, the DC-link voltage and the gate voltage. This correlation is shown in module datasheets. It should,

however, be considered that the driver is turned on at +15V and turned off at -7V. Therefore, the gate voltage will change by

22V during each switching procedure. Unfortunately, many datasheets do not show negative gate voltages. In order to

determine the required charge, the upper leg of the charge curve may be prolonged to +22V for determination of

approximate charge per switch.

The medium output current of the driver is determined by the switching frequency and the gate charge. The maximum

switching frequency may be calculated with the shown equation and is limited by the average current of the driver power

supply and the power dissipation of driver components.

Calculation Switching Frequency

Maximum Switching Frequency @ different Gate Charges @ T_amb=25°C

60 kHz

50 kHz

40 kHz

30 kHz

20 kHz

Iout_AVmax

f_max

=

Q_GE

f_max

Iout_AVmax

Q_GE

:

Maximum switching frequency *

Maximum output average current

Gate charge of the driven IGBT

:

10 kHz

with external boost capacitors

* @ T_amb=25°C

0 kHz

0 µC

1 µC

2 µC

3 µC

4 µC

5 µC

6 µC

7 µC

gate charge

Calculation Average Output Current

Average Output Current as a Function of the Ambient Temperature

60 mA

50 mA

40 mA

30 mA

20 mA

10 mA

0 mA

Iout_AV= f_sw× Q_GE

Iout_AV

:

Average output current

Switching frequency

f_sw:

Q_GE

:

Gate charge of the driven IGBT

0 °C

10 °C

20 °C

30 °C

40 °C 50 °C

ambient temperature

60 °C

70 °C

80 °C

90 °C

Please note:

The maximum value of the switching frequency is limited to 50kHz due to switching reasons.

Insulation

Magnetic transformers are used for insulation between gate driver primary and secondary side. The transformer set consists

of pulse transformers which are used bidirectional for turn-on and turn-off signals of the IGBT and the error feedback

between secondary and primary side, and a DC/DC converter. This converter provides a potential separation (galvanic

separation) and power supply for the two secondary (TOP and BOT) sides of the driver. Thus, external transformers for

external power supply are not required.

Creepage and Clearance Distance in mm

Primary to secondary

Min. 12,2

6

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SKYPER^®32 R UL

Isolation Test Voltage

The isolation test voltage represents a measure of immunity to transient voltages. The maximum test voltage and time

applied once between input and output, and once between output 1 and output 2 are indicated in the absolute maximum

ratings. The high-voltage isolation tests and repeated tests of an isolation barrier can degrade isolation capability due to

partial discharge. Repeated isolation voltage tests should be performed with reduced voltage. The test voltage must be

reduced by 20% for each repeated test.

The isolation of the isolation barrier (transformer) is checked in the part. With exception of the isolation barrier, no active

parts, which could break through are used. An isolation test is not performed as a series test. Therefore, the user can

perform once the isolation test with voltage and time indicated in the absolute maximum ratings.

Please note:

An isolation test is not performed at SEMIKRON as a series test.

Auxiliary Power Supply

A few basic rules should be followed when dimensioning the customer side power supply for the driver. The following table

shows the required features of an appropriate power supply.

Requirements of the auxiliary power supply

Regulated power supply

+15V 4%

50ms

Please note:

Maximum rise time of auxiliary power supply

Minimum peak current of auxiliary supply

Power on reset completed after

Do not apply switching

signals during power on

reset.

1A

150ms

The supplying switched mode power supply may not be turned-off for a short time as consequence of its current limitation.

Its output characteristic needs to be considered. Switched mode power supplies with fold-back characteristic or hiccup-mode

can create problems if no sufficient over current margin is available. The voltage has to rise continuously and without any

plateau formation as shown in the following diagram.

Rising slope of the power supply voltage

If the power supply is able to provide a higher current, a peak current will flow in the first instant to charge up the input

capacitances on the driver. Its peak current value will be limited by the power supply and the effective impedances (e.g.

distribution lines), only.

It is recommended to avoid the paralleling of several customer side power supply units. Their different set current limitations

may lead to dips in the supply voltage.

The driver is ready for operation typically 150ms after turning on the supply voltage. The driver error signal

PRIM_nERROR_OUT is operational after this time. Without any error present, the error signal will be reset.

To assure a high level of system safety the TOP and BOT signal inputs should stay in a defined state (OFF state, LOW)

during driver turn-on time. Only after the end of the power-on-reset, IGBT switching operation shall be permitted.

7

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SKYPER^®32 R UL

Under Voltage Protection of driver power supply (UVP)

The internally detected supply voltage of the driver has an under voltage protection. The table below gives an overview of

the trip level.

Supply voltage

UVP level

Regulated +15V 4%

13,5V

If the internally detected supply voltage of the driver falls below this level, the IGBTs will be switched off (IGBT driving

signals set to LOW). The input side switching signals of the driver will be ignored. The error memory will be set, and the

output PRIM_nERROR_OUT changes to the HIGH state.

Input Signals

The signal transfer to each IGBT is made with pulse transformers, used for switching on and switching off of the IGBT. The

inputs have a Schmitt Trigger characteristic and a positive / active high logic (input HIGH = IGBT on; input LOW = IGBT off).

It is mandatory to use circuits which switch active to +15V and 0V. Pull up and open collector output stages must not be

used for TOP / BOT control signals. It is recommended choosing the line drivers according to the demanded length of the

signal lines.

Please note:

It is not permitted to apply switching pulses shorter than 1µs.

TOP / BOT Input

A capacitor is connected to the input to obtain high noise immunity.

This capacitor can cause for current limited line drivers a little delay of

few ns, which can be neglected. The capacitors have to be placed as

close as possible to the driver interface.

Short Pulse Suppression (SPS)

This circuit suppresses short turn-on and off-pulses of incoming signals. This way the IGBTs are protected against spurious

noise as they can occur due to bursts on the signal lines. Pulses shorter than 625ns are suppressed and all pulses longer

than 750ns get through for 100% probability. Pulses with a length in-between 625ns and 750ns can be either suppressed or

get through.

Pulse pattern – SPS

shortꢀpulses

PRIM_TOP/BOT_INꢀ(HIGH)

PRIM_TOP/BOT_INꢀ(LOW)

SEC_TOP/BOT_IGBT_ON

SEC_TOP/BOT_IGBT_OFF

8

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SKYPER^®32 R UL

Failure Management

Any error detected will set the error latch and force the output PRIM_nERROR_OUT into HIGH state. Switching pulses from

the controller will be ignored. Connected and switched off IGBTs remain turned off. The switched off IGBTs remain turned

off. A reset of the latched error memory is only possible if no failure is present anymore and if the TOP and BOT input

signals are set to the LOW level for a period of t_pERRRESET> 9µs.

The output PRIM_nERROR_OUT is an open collector output. For the error evaluation an external pull-up-resistor is

necessary pulled-up to the positive operation voltage of the control logic (LOW signal = no error present, wire break safety is

assured).

Open collector error transistor

Application hints

An external resistor to the controller logic high level is required. The

resistor has to be in the range of V / I_max< R_{pull_up}< 10kꢁ.

PRIM_nERROR_OUT can operate to maximum 30V and can switch

a maximum of 15mA.

Example:

For V = +15V the needed resistor should be in the range

R_{pull_up}= (15V/15mA) … 10kꢁ ⇒ 1kꢁ… 10kꢁ.

Please note:

The error output PRIM_ERROR_OUT is not short circuit proof.

Shut Down Input (SDI)

The shut down input / error input signal can gather error signals of other hardware components for switching off the IGBT

(input HIGH = no turn-off; input LOW = turn-off).

A LOW signal at PRIM_nERROR_IN will set the error latch and force the output PRIM_nERROR_OUT into HIGH state.

Switching pulses from the controller will be ignored. A reset of the latched error memory is only possible if no LOW signal at

PRIM_nERROR_IN is present anymore and if the TOP and BOT input signals are set to the LOW level for a period of

t_pERRRESET> 9µs.

The SDI function can be disabled by no connection or connecting to 5V.

Connection SDI

9

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SKYPER^®32 R UL

Dead Time generation (Interlock TOP / BOT) (DT)

The DT circuit prevents, that TOP and BOT IGBT of one half bridge are switched on at the same time (shoot through). The

dead time is not added to a dead time given by the controller. Thus the total dead time is the maximum of "built in dead time"

and "controller dead time". It is possible to control the driver with one switching signal and its inverted signal.

Please note:

The generated dead time is fixed and cannot be changed.

Pulse pattern – DT

ꢀ

The total propagation delay of the driver is the sum of

interlock dead time (t_TDand driver input output signal

)

propagation delay (t_d(on;off)IO) as shown in the pulse pattern.

Moreover the switching time of the IGBT chip has to be taken

into account (not shown in the pulse pattern).

ꢀ

In case both channel inputs (PRIM_TOP_IN and

PRIM_BOT_IN) are at high level, the IGBTs will be turned off.

If only one channel is switching, there will be no interlock

dead time.

Please note:

No error message will be generated when overlap of switching signals occurs.

Dynamic Short Circuit Protection by V_CEsatmonitoring / de-saturation monitoring (DSCP)

The DSCP circuit is responsible for short circuit sensing. It monitors the collector-emitter voltage V_CEof the IGBT during its

on-state. Due to the direct measurement of V_CEsaton the IGBT's collector, the DSCP circuit switches off the IGBTs and an

error is indicated.

The reference voltage V_CErefmay dynamically be adapted to the IGBTs switching behaviour. Immediately after turn-on of the

IGBT, a higher value is effective than in steady state. This value will, however, be reset, when the IGBT is turned off. V_CEstat

is the steady-state value of V_CErefand is adjusted to the required maximum value for each IGBT by an external resistor R_CE

.

It may not exceed 10V. The time constant for the delay (exponential shape) of V_CErefmay be controlled by an external

capacitor C_CE, which is connected in parallel to R_CE. It controls the blanking time t_blwhich passes after turn-on of the IGBT

before the V_CEsatmonitoring is activated. This makes an adaptation to any IGBT switching behaviour possible.

Reference Voltage (V_CEref) Characteristic

After t_blhas passed, the V_CEmonitoring will be triggered as soon as V_CE> V_CErefand will turn off the IGBT. The error

memory will be set, and the output PRIM_nERROR_OUT changes to the HIGH state. Possible failure modes are shows in

the following pictures.

10

Rev 0 – 11.08.2010

SKYPER^®32 R UL

Short circuit during operation

Turn on of IGBT too slow *

Short circuit during turn on

* or adjusted blanking time too short

Adjustment of DSCP

The external components R_CEand C_CEare applied for adjusting the steady-state threshold the blanking time.

Connection R_CEand C_CE

Dimensioning of R_CEand C_CE

V









V_CEstat+ R_VCE

⋅

kΩ





R_CE

[

kΩ

]

= −17kΩ ⋅ln 1−





8,5V





µ

s

t_bl

[µs

]

− 2,5

µs − 0,11

⋅ R_CE

kΩ

C_CE

[

pF

=

µs

0,00323

pF

V_CEstat

t_blx

:

Collector-emitter threshold static monitoring voltage

Blanking time

:

V_{CEstat_max}= 8V (R_VCE= 0ꢁ)

V_{CEstat_max}= 7V (R_VCE= 1kꢁ)

Please Note:

The equations are calculated considering the use of high voltage diode

BY203/20S. The calculated values V_CEstatand t_blare typical values at room

temperature. These values can and do vary in the application (e.g. tolerances of

used high voltage diode, resistor R_CE, capacitor C_CE).

The DSCP function is not recommended for over current protection.

Application hints

If the DSCP function is not used, for example during the experimental phase, SEC_TOP_VCE_IN must be connected with

SEC_TOP_GND for disabling SCP @ TOP side and SEC_BOT_VCE_IN must be connected with SEC_BOT_GND for disabling SCP @

BOT side.

11

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SKYPER^®32 R UL

High Voltage Diode for DSCP

The high voltage diode blocks the high voltage during IGBT off state. The connection of this diode between driver and IGBT

is shown in the following schematic.

Connection High Voltage Diode

Characteristics

ꢀ

Reverse blocking voltage of the diode shall be higher than the

used IGBT.

Reverse recovery time of the fast diode shall be lower than V_CE

rising of the used IGBT.

Forward voltage of the diode: 1,5V @ 2mA forward current

(T_j=25°C).

A collector series resistance R_VCE(1kΩ / 0,4W) must be

connected for 1700V IGBT operation.

Gate resistors

The output transistors of the driver are MOSFETs. The sources of the MOSFETs are separately connected to external

terminals in order to provide setting of the turn-on and turn-off speed of each IGBT by the external resistors R_Gonand R_Goff

.

As an IGBT has input capacitance (varying during switching time) which must be charged and discharged, both resistors will

dictate what time must be taken to do this. The final value of the resistance is difficult to predict, because it depends on

many parameters as DC link voltage, stray inductance of the circuit, switching frequency and type of IGBT.

Connection R_Gon, R_Goff

Application Hints

The gate resistor influences the switching time, switching losses,

dv/dt behaviour, etc. and has to be selected very carefully. Due to

this influence a general value for the gate resistors cannot be

recommended. The gate resistor has to be optimized according to

switching behaviour and over voltage peaks within the specific

circuitry.

By increasing R_Gonthe turn-on speed will decrease. The reverse

peak current of the free-wheeling diode will diminish.

By increasing R_Goffthe turn-off speed of the IGBT will decrease. The

inductive peak over voltage during turn-off will diminish.

In order to ensure locking of the IGBT even when the driver supply

voltage is turned off, a resistance (R_GE) has to be integrated.

Please note:

Do not connect the terminals SEC_TOP_IGBT_ON with SEC_TOP_IGBT_OFF and SEC_BOT_IGBT_ON

with SEC_BOT_IGBT_OFF, respectively.

12

Rev 0 – 11.08.2010

SKYPER^®32 R UL

External Boost Capacitors (BC)

The rated gate charge of the driver may be increase by additional boost capacitors to drive IGBT with large gate

capacitance.

Connection External Boost Capacitors

Dimensioning of C_boost

ꢀ

C_boost15P[µF] = Q_GE[µC] × 1/V - 2,2µF

C_boost8N[µF] = Q_GE[µC] × 2/V - 4,7µF

Q_GE: Gate charge of the IGBT @ V_GE= -7 …+15V

Minimum rated voltage C_boost15P: 25V

Minimum rated voltage C_boost8N: 16V

Type of capacitor: ceramic capacitor

Please consider the maximum rating four output charge per

pulse of the gate driver.

Application Hints

The external boost capacitors should be connected as close as

possible to the gate driver and to have low inductance.

Application Example

Connection Schematic

DC+

SKYPER^TM32

SEC_TOP_VCE_CFG

SEC_TOP_VCE_IN

SEC_TOP_15P

BY203/20S

330pF

18k

50V

SEC_TOP_15P

SEC_TOP_GND

SEC_TOP_IGBT_ON

Ron

PRIM_PWR_GND

4,75k

SEC_TOP_GND

PRIM_PWR_GND

PRIM_nERROR_OUT

PRIM_nERROR_IN

PRIM_PWR_GND

PRIM_TOP_IN

SEC_TOP_IGBT_OFF

10k

ERROR OUT

Roff

SEC_TOP_8N

2,2µF

25V

4,7µF

16V

load

SEC_BOT_VCE_CFG

SEC_BOT_VCE_IN

SEC_BOT_15P

BY203/20S

INPUT TOP

INPUT BOT

PRIM_BOT_IN

330pF

50V

18k

PRIM_PWR_15P

SEC_BOT_15P

+15V

SEC_BOT_GND

SEC_BOT_IGBT_ON

SEC_BOT_GND

SEC_BOT_IGBT_OFF

SEC_BOT_8N

1nF

220µF

35V

1nF

Ron

100V

10k

Roff

2,2µF

25V

4,7µF

16V

SEC_BOT_8N

DC-

-

application example for 1200V IGBT

_out/pulse= 5µC

V_CEref= 5,5V

t_bl= 5,5µs

Q

13

Rev 0 – 11.08.2010

SKYPER^®32 R UL

Mounting Notes

Soldering Hints

Finished Hole & Pad Size in mm

The temperature of the solder must not exceed 260°C, and solder time must

not exceed 10 seconds.

The ambient temperature must not exceed the specified maximum storage

temperature of the driver.

The solder joints should be in accordance to IPC A 610 Revision D (or later) -

Class 3 (Acceptability of Electronic Assemblies) to ensure an optimal

connection between driver core and printed circuit board.

Please note:

The driver is not suited for hot air reflow or infrared reflow processes.

The connection between driver core and printed circuit board should be mechanical reinforced by using support posts.

Use of Support Posts

Product information of suitable support posts and

distributor contact information is available at e.g.

http://www.richco-inc.com (e.g. series DLMSPM,

LCBST).

Please note:

The use of agressive materials in cleaning and potting process of driver core may be detrimental for the device parameters. If the driver

core is coated by the user, any warranty (Gewährleistung) expires.

Environmental Conditions

The driver core is type tested under the environmental conditions below.

Conditions

Values (max.)

Vibration

Sinusoidal sweep 20Hz … 500Hz, 5g, 26 sweeps per axis (x, y, z)

-

Tested acc. IEC 68-2-6

Connection between driver core and printed circuit board mechanical reinforced by using support posts.

Shock

Half-sinusoidal pulse, 5g, shock width 18ms, 3 shocks in each direction ( x, y, z), 18 shocks in total

-

Tested acc. IEC 68-2-27

Connection between driver core and printed circuit board mechanical reinforced by using support posts.

The characteristics and further environmental conditions are indicated in the data sheet.

14

Rev 0 – 11.08.2010

SKYPER^®32 R UL

Marking

Every driver core is marked. The marking contains the following items.

Part Marking Information

The Data Matrix Code is described as follows:

ꢀ Type:

EEC 200

ꢀ Standard:

ꢀ Cell size:

ꢀ Dimension:

ICO / IEC 16022

0,254 - 0,3 mm

5 × 5 mm

ꢀ The following data is coded:

ꢁ

XXXXXXXXYY

ꢂ

ꢃ

ZZZZ

ꢄ

ꢅ

VVVV

ꢁ

8 digits

2 digits

part number

version number

1. SEMIKRON part number (8 digits) + version number (2 digits)

2. Date code (4 digits): YYWW

ꢂ

ꢃ

ꢄ

ꢅ

1 digit

4 digits

1 digit

4 digits

blank

date code

blank

3. Continuous number referred to date coce (4 digits)

4. Data matrix code

continuous number

DISCLAIMER

SEMIKRON reserves the right to make changes without further notice herein to improve reliability, function or design.

Information furnished in this document is believed to be accurate and reliable. However, no representation or warranty is

given and no liability is assumed with respect to the accuracy or use of such information. SEMIKRON does not assume

any liability arising out of the application or use of any product or circuit described herein. Furthermore, this technical

information may not be considered as an assurance of component characteristics. No warranty or guarantee expressed

or implied is made regarding delivery, performance or suitability. This document supersedes and replaces all information

previously supplied and may be superseded by updates without further notice.

SEMIKRON products are not authorized for use in life support appliances and systems without the express written

approval by SEMIKRON.

www.SEMIKRON.com

15

Rev 0 – 11.08.2010


型号：	SKYPER32RUL
厂家：	SEMIKRON INTERNATIONAL
描述：	IGBT Driver Core IGBT驱动器的核心驱动器双极性晶体管
文件：	总16页 (文件大小：444K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

SKYPER32RUL [SEMIKRON]

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