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The drive circuit for IGBTs that’s a prizewinner

The SCALE driver is a winning project of the competition

organized by “Technology Center Switzerland 1998”.

And ABB Switzerland AG honored the development of

the SCALE driver by distinguishing it as the “best project

in power electronics 1998”.

The SCALE drivers from CONCEPT are based on a chip set that was

developed specifically for the reliable driving and safe operation of

IGBTs and power MOSFETs.

The name “SCALE” is an acronym for the most outstanding properties of the SCALE

series of drivers:

SCALE = Scaleable, Compact, All purpose, Low cost and Easy to use.

Product Highlights

Applications

✔ Suitable for IGBTs and power MOSFETs

✔ Short circuit and overcurrent protection

✔ Extremely reliable, long service life

✔ High gate current from ±6A to ±30A

✔ Electrical isolation from 500V to over 10kV

✔ Electrically isolated status acknowledgement

✔ Monitoring of power supply and self-monitoring

✔ Switching frequency DC to >100kHz

✔ Duty cycle: 0... 100%

✔ Inverters

✔ Motor drive technology

✔ Traction

✔ Railroad power supplies

✔ Converters

✔ Power engineering

✔ Switched-mode power supplies

✔ Radiology and laser technology

✔ DC/DC converter

✔ High dv/dt immunity, guaranteed >100,000V/µs ✔ Research

✔ Complete with DC/DC converter

✔ RF generators and converters

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Description and Application Manual

Contents

SCALE driver application – it’s never been so simple ...........................4

A brief introduction............................................................................4

Mode selection and dead times........................................................................................ 4

Voltage supply and logic level.......................................................................................... 4

Signal inputs and status outputs ........................................................................................ 5

Connecting the IGBTs ...................................................................................................... 5

Defining the turn-off threshold ........................................................................................... 5

Application example: 30kW inverter with six-pack driver ..................6

What is a “SCALE” driver?..................................................................7

Scaleable....................................................................................................................... 7

Compact........................................................................................................................ 8

All purpose..................................................................................................................... 8

Low cost......................................................................................................................... 8

Easy to use..................................................................................................................... 9

Your benefit: the application advantages of SCALE drivers..................9

Reliable operation........................................................................................................... 9

Genuine electrical isolation .............................................................................................. 9

Reliable transformer principle ......................................................................................... 10

Delay times .................................................................................................................. 10

Status acknowledgements .............................................................................................. 10

Ideal layout of the terminals............................................................................................ 10

How exactly do they work? The SCALE drivers in detail....................11

Overview..................................................................................................................... 11

The concept of the SCALE driver circuit............................................................................ 11

Block diagram of the “Logic-to-Driver-Interface” LDI 001 .................................................... 12

The power supply: the integrated DC/DC converter.......................................................... 13

The electronic interface: LDI 001..................................................................................... 13

Block diagram of the “Logic-to-Driver-Interface“ LDI 001 .................................................... 14

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The Intelligent Gate Driver: IGD 001............................................................................... 15

Block diagram of the ”Intelligent Gate Driver“ IGD 001 .................................................... 16

Absolute safety: the protection concept.............................................17

Short circuit and over-current protection........................................................................... 17

Power supply monitoring................................................................................................ 18

Selecting the operating mode...........................................................19

Direct mode.................................................................................................................. 19

Half-bridge mode with dead time.................................................................................... 20

Practical Part 1: the input side..........................................................22

Pin GND...................................................................................................................... 22

Pin VDC (voltage supply DC/DC converter) ..................................................................... 22

Pin VDD (voltage supply electronics input side)................................................................. 22

Pin VL / Reset (define logic level/acknowledge error) ....................................................... 23

Pin MOD (mode selection) ............................................................................................. 24

Pin InA (signal input A).................................................................................................. 25

Pin InB (signal input B)................................................................................................... 25

Pin SOx (status outputs).................................................................................................. 25

Pin RCx (RC networks for the dead times)......................................................................... 26

Practical Part 2: the power side........................................................27

Pin Gx (gate terminal).................................................................................................... 27

Pin Ex (emitter terminal) ................................................................................................. 28

Pin Cx (collector sense).................................................................................................. 28

Pin Rthx (reference resistor)............................................................................................. 29

Layout and wiring ......................................................................................................... 30

The really fast variant: evaluation boards ........................................31

If you need any help, simply call our technical support.....................31

Important information: the SCALE driver data sheets.........................32

Quite special: customized SCALE drivers............................................32

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Description and Application Manual

SCALE driver application – it’s never been so simple

As soon as you’ve read the following eleven and a half pages, you’ll

be able to use a SCALE driver.

Power electronics really has become that easy!

And you will learn directly from each paragraph where to access all

the details you need to obtain more detailed information. For you will

certainly want to know more about some of the topics covered.

Everything is described in full detail in the section “How exactly do

they work? The SCALE drivers in detail" from page 11 onwards, so

that you can find all the information that you need.

At the end of the brief introduction you will see from an example

how easily a current inverter can be put together with a SCALE driver.

A brief introduction

Mode selection and dead times

First of all select the mode in which you wish to operate the SCALE driver. There are

two modes: direct mode and half-bridge mode.

In direct mode, there are no links between the individual channels of a multiple driver.

And that’s how it works: the MOD input is connected to VCC and the inputs RC1

through RCn (depending on how many channels the driver has) are connected to

GND. In half-bridge mode, the chip set can directly generate the required dead times.

For half-bridge operation, the MOD input is connected to GND and an RC network is

connected to inputs RC1 through RCn for each channel to generate the dead time.

See page 26 for the dimensioning of the RC networks.

Voltage supply and logic level

The GND terminals (some SCALE drivers have several GND and several voltage

supply terminals) are connected to the ground terminal of the voltage supply unit. The

VDD and VDC terminals should be connected to a stabilized 15V supply source.

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The VL/Reset pin is used to define the logic level and to erase the error memory. The

circuits for 5V and 15V logic levels are shown in Fig. 11. There’s more on this topic

from page 23 onwards.

Signal inputs and status outputs

The PWM signals of the control electronics are applied to inputs A and B. Depending

on the selected mode, these inputs have a different function: in direct mode, input A is

assigned directly to channel 1, whereas input B controls channel 2.

In half-bridge mode, the PWM signal is applied to input A whereas input B carries the

release signal for both channels. There’s more on this topic on page 25.

The status outputs are “open collector” outputs and can thus be simply matched to all

logic levels and families. The outputs lead simply to the logic and are connected to the

logic supply via a pull-up resistor. There’s more on this topic on page 25.

Connecting the IGBTs

The auxiliary emitter (emitter control terminal) is connected to output “Ex” (where “x”

stands for the number of the drive channel in multi-channel drivers). In the same way,

the gate is connected to output “Gx”; but via a gate resistor or a gate resistor

network. There’s more on this topic from page 27 onwards.

The collector sense terminal “Cx” is connected via a diode to the collector of the IGBT.

On this point, read the hints from page 28 onwards and any additional hints in the

data sheet of the SCALE driver used.

Defining the turn-off threshold

The turn-off threshold and the response time are defined by a resistor connected

between the terminal “Rthx” and the emitter terminal “Ex”. An explanation of these

terms is found from page 17 onwards. A table or a diagram of the turn-off threshold

and the response time can be obtained from the data sheet of the relevant SCALE

driver.

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Description and Application Manual

Application example: 30kW inverter with six-pack driver

The drawing in Fig. 1 shows all the required components of the current inverter circuit.

The circuit diagram clearly illustrates the level of integration of the driver solution and

its simplicity in application.

U

V

W

Not connected

eupec

BSM100GD120DN2

DC(+)

21A

21B

21C

13A

13B

13C

DC(+)

+

20A

20B

20C

14A

14B

14C

DC(-)

CONCEPT 6SD106E Six-pack driver

+15V

GND

+15V GND

Fig. 1 Complete circuit diagram of the 30kW inverter

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The circuit diagram in Fig. 1 shows all the components required for the inverter circuit.

The diagram thus illustrates clearly the level of integration of the driver solution and its

simplicity of application.

Compared with IPM solutions, which require more external components but offer no

additional flexibility in the selection of the switching properties, the SCALE driver

solution has the advantage of allowing the switching characteristic to be defined in

any way required with the few components that are still located externally. In

addition, the level of the protection cut-out (Vce monitoring circuit) can be freely

selected.

For this example, we assume that the drive controller already generates the dead

times internally. It thus supplies six drive signals. The controller operates with TTL

levels, so that we set the input VL (pins 8, 20, 32) to 4.7V. The PWM inputs are

marked with “Input 1”...”Input 6”.

However, the controller still has only one error input: so we must combine our six

status acknowledgements into a single signal “status".

The other inputs and outputs are now quickly connected in the correct way in

accordance with the description given on the preceding pages: the result is the

completed circuit diagram shown in Fig. 1.

And now you can switch on...

What is a “SCALE” driver?

"SCALE" stands for Scaleable, Compact, All-purpose, Low-cost and Easy-to-use.

This is a concise enumeration of the most outstanding properties of SCALE drivers.

Scaleable

One of the most important properties of the SCALE driver chip set is its scaleability. In

this context, the term scaleable means that the chip set — in contrast to all previous

approaches to integrated drive circuits — can be used for a very large range of

applications. The SCALE driver chip set can be used to implement solutions for diverse

drive currents (gate currents) and various drive powers. SCALE drivers are well suited

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Description and Application Manual

for almost any switching frequency, any modulation mode and not least for isolation

voltages of practically any magnitude.

SCALE drivers can be used to construct power sections from the kilowatt to the

megawatt range.

Compact

SCALE drivers accommodate all the necessary components on a minimum surface

area. They cover the following functions: driving, monitoring, status

acknowledgement, isolated voltage supply (DC/DC converters) and electrical isolation

of all signals between the control electronics and the power section.

SCALE drivers are currently the most compact driver solutions on the market with this

range of functions.

All purpose

The SCALE driver chip set offers maximum flexibility of operation: by switching the

mode accordingly, a choice can be made between half-bridge or direct-mode

operation.

In half-bridge operation, the chip set can generate the required dead times directly. In

direct mode, there are no links between the individual channels of a multiple driver.

Low cost

SCALE drivers are high-quality driver circuits for IGBTs and power MOSFETs with an

outstanding price/performance ratio. A SCALE driver contains all the components that

can possibly be integrated. It encompasses the driver function itself, plus monitoring,

acknowledgement, power supply (DC/DC converter) and electrical isolation of all

signals.

SCALE drivers are the most inexpensive drivers on the market offering this

performance.

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Easy to use

The interface to the electronics is very simple: the SCALE driver chip set can handle all

standard logic levels between 5V and 15V. The inputs have a Schmitt trigger

characteristic and make no special demands on the input signals. The status

acknowledgements are designed as open-collector outputs and are thus compatible

with all the usual logic levels.

Application is extremely simple because a SCALE driver contains all the functions of

an intelligent driver, and the drive signals, the status acknowledgement and the power

supply are completely isolated from the power section.

Application of SCALE drivers with standard IGBT modules is in most cases simpler

than an IPM, but without any loss in flexibility.

Your benefit:

the application advantages of SCALE drivers

Reliable operation

Gate driving with a bipolar control voltage (typically 15V) allows the reliable

operation of IGBT modules of any size from any manufacturer. Thanks to the high

interference immunity attained by using a negative gate voltage, a number of power

MOSFET or IGBT modules can be connected in parallel.

Genuine electrical isolation

SCALE drivers contain miniaturized transformers for the isolation of all channels.

These offer outstanding isolation properties and low coupling capacitances.

The SCALE driver can be used to obtain isolation voltages of practically any

magnitude. The product-specific isolation data relating to the individual versions can

be found in the data sheets dealing with the individual types.

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Description and Application Manual

Reliable transformer principle

Pulse transformers were selected because they offer the following advantages over all

other designs: minimum delay times, no degradation effects, maximum service life

and the ability to obtain isolation voltages of any desired magnitude.

The MTBF (failure probability) of a pulse transformer of the kind used in the SCALE

drivers is better by a factor of 20 than that of a high-quality optical coupler, for

instance, and about 200 times better than that of a good fiber-optic link.

The extremely high interference immunity of at least 100kV per microsecond

predestines the SCALE driver to applications in which large potential differences and

large potential jumps occur between the power section and the control electronics.

Delay times

The delay times through the complete driver circuit are around 300...350ns. The

delays for the positive and the negative edges are symmetrical.

There are almost no differences in delay time between the different drivers, an

important factor for ensuring operation without offset problems as well as for parallel

circuits. Signal transfer is practically jitter-free.

Status acknowledgements

The pulse transformer is operated bi-directionally - for transferring both the drive

information and the status acknowledgement.

Ideal layout of the terminals

The terminal pins of the drivers are arranged so that the layout can be kept very

simple and the logic signal flow (input signal

maintained.

drive circuit

power transistors) is

Page 10

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Description and Application Manual

How exactly do they work? The SCALE drivers in detail

Overview

SCALE drivers are available in various versions in order to satisfy the different

requirements in terms of driver performance, number of drive channels, isolation

requirements and to cover the diversity of applications and standards.

The information given in this description is identical or practically so for all versions.

The product-specific data relating to the individual versions can be found in the data

sheets dealing with the individual types.

The concept of the SCALE driver circuit

The interface to the control electronics forms the first building block of the SCALE chip

set: the LDI (LDI = Logic to Driver Interface). An LDI drives two channels. The PWM

signals applied to inputs A and B are processed so that the drive information can be

fed to a pulse transformer for each channel.

The pulse transformers are responsible for the electrical separation of the drive

information. At the same time, they are also used in the reverse direction in order to

return the status information of each channel to the LDI.

The second building block of the SCALE driver chip set is used once for each drive

channel. This is the IGD (IGD = Intelligent Gate Driver). It receives the pulse-coded

information from the transformers and reconstructs the original PWM signal from it.

This is then amplified, making a gate current of several amps available to drive the

power semiconductor. Furthermore, the IGD contains protection functions that

safeguard the power semiconductor from harmful operating conditions.

The DC/DC converter makes the electrically separated power supply available to the

individual driver channels. The SCALE drivers require a simple stabilized 15V DC

supply.

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Description and Application Manual

Block diagram of the “Logic-to-Driver-Interface” LDI 001

Rth

IGD

Rg

VDD

GND

Viso1

LDI

Rth

Rg

IGD

Viso2

VDC

Viso1

Viso2

PWM

oscillator

GND

Interface on

Electronic Level

Electrical

Isolation

Driver on

Power Level

Power

Semiconductor

(external)

SCALE Driver Module

Fig. 2 Block diagram of a two-channel SCALE driver

The block diagram shows a two-channel driver based on the SCALE chip set. For a

three-phase version, there is only one PWM oscillator, all other components are

present in triplicate.

For each channel, the SCALE drivers contain the electrical separation between the

control and power sides, an over-current and short-circuit protection circuit for the

power transistors, a feed monitoring circuit, a status acknowledgement circuit as well

as an electrically separated power supply for the drive electronics via an integrated

DC/DC converter.

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The power supply: the integrated DC/DC converter

All standard SCALE drivers contain a DC/DC converter. This is used for the power

supply of the individual driver channels. The electrical separation of the DC/DC

converters allows the SCALE drivers to be supplied from the electronic power unit

which is in most cases present in any case.

Drive energies of different magnitudes are required depending on the application –

and especially on the clock frequency and gate charge of the used power

semiconductors. SCALE drivers are therefore offered with differently dimensioned

DC/DC converters. The exact data of the relevant DC/DC converter can be obtained

from the data sheets of the individual SCALE drivers.

The electronic interface: LDI 001

PWM signals of the kind generated by the control electronics cannot simply be

transferred via transformers. This is particularly difficult when a large frequency range

and various duty cycle ratios are to be transmitted.

The LDI 001 logic-to-driver interface was developed for this reason. This IC has the

following main functions:

1) Creation of a simple interface for the user. Both signal inputs have a Schmitt

trigger characteristic

2) Simple matching to the logic level used in the electronics (5V...15V)

3) Forming the dead times in a half bridge, where required. This function can also

be deactivated

4) Coding of the PWM signals so that they can be transmitted via a pulse

transformer

5) Evaluation of the status acknowledgement transmitted in coded form and its

subsequent buffering so that a quasi-static acknowledgement signal is available

to the user

A SCALE driver can be connected directly and with no additional components to any

logic circuit. In the same way, however, driving is also possible via longer cables:

with a 15V level, acceptable signal-to-noise ratios are obtained in such applications.

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Description and Application Manual

The possibility of generating the dead times directly with the SCALE driver obviates

the external circuits that are usually required.

These functions make SCALE drivers directly compatible with practically all available

interfaces and levels. As a rule, therefore, the interfaces usually required for other

driver solutions are obviated.

Block diagram of the “Logic-to-Driver-Interface“ LDI 001

RC1

RC2

Mode Selector

3

6

7

V

Channel 2

Transformer

Channel 2

11

VCC

GND

13

12

VL

Reset

Pulse

Stop

Logic

9

Hi

Trafo

Interface

VL

2

4

Mode

Logic

Dual

Error

Logic

Dead-

Time

Error

Input A

Lo

Reset

Channel 1

Transformer

Channel 1

Input A

16

Pulse

Logic

Input B / Enable

5

Input B

Status 2

Status 1

14

8

1

Error Channel 2

Error Channel 1

Trafo

Interface

Error

Logic

Error

Reset

CONCEPT LDI 001

Fig. 3 Block diagram of the LDI 001

All necessary functions of an intelligent gate driver are integrated in the IGD 001: the

transformer interface, overload and short-circuit protection, blocking time logic, status

acknowledgement, monitoring of the supply voltage and the output stage.

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The Intelligent Gate Driver: IGD 001

All necessary functions of an intelligent gate driver are integrated in the IGD 001: the

transformer interface, overload and short-circuit protection, blocking time logic, status

acknowledgement, monitoring of the supply voltage and the output stage.

An IGD 001 intelligent gate driver is used for each drive channel. This IC has the

following functions:

1) Decoding the PWM signals transferred via the pulse transformer

2) Amplifying the PWM signals to drive the final stage

3) Power Semiconductor desaturation monitoring (short circuit & overcurrent

protection)

4) Under-voltage monitoring

5) Generating response and blocking times

6) Status acknowledgement to the controller (LDI 001)

All necessary protection functions that safeguard the semiconductor from over-current

and short circuit are present locally in every driver (and thus every power

semiconductor).

In the same way, the local under-voltage monitoring circuit ensures for each channel

that the driver is released only when the supply voltage is sufficiently high. This

reliably avoids the critical condition of “half” driving of power semiconductors.

Every time an error is detected, a blocking time is applied locally on the driver. In

particular after a short circuit, power semiconductors require a “pause” in order to

cool down again before the next drive pulse is released.

The status (error or normal) can be queried at any time from the pre-connected

LDI 001.

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Block diagram of the ”Intelligent Gate Driver“ IGD 001

V

Vce Monitoring

13

12

V

Viso

Transformer

Interface

Rref

3

4

5

1

2

Pulse

Flip-Flop

Dm

Rm

Ca

Cx

Error

Pulse Logic

SO

8

7

Error

Reset

Uce Fail

Timer

Cb

RGx

Gx

Ex

V

15

10

Vcc Fail

Rthx

6

Power Supply

Supervisor

CONCEPT IGD 001

SCALE Driver Module

Fig. 4 Block diagram of IGD 001 intelligent gate driver with external wiring

All the functions shown in the inner block of Fig. 4 are integrated on the chip. The

components shown in the outer block are contained in the SCALE driver modules. This

means that practically no external components are required.

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Absolute safety: the protection concept

Short circuit and over-current protection

Every channel of a SCALE driver is equipped with a Vce monitoring circuit. A resistor

(Rth in Fig. 4) is used as the reference element for defining the turn-off threshold.

During the response time, the Vce monitoring circuit is inactive. The response time is

the time that elapses after turn-on of the power semiconductor until the transistor is

saturated.

The characteristic described below is

shown graphically in Fig. 6.

Driver

Input

Voltage

+VL

0V

After a Vce or under-voltage error, the

blocking time is initiated. During this

period, the driver blocks the power

semiconductor and accepts no drive

signals. The blocking time is a function

that runs locally on every driver

channel and is implemented within the

IGD 001. It starts immediately after the

threshold of the VCE monitoring circuit

set (with reference resistor Rth) has

been exceeded. With the consequent

edge change of the drive signal, the

“error” information is transferred for

storage to the LDI 001, whose status

output SOx for the corresponding

channel now becomes active (Lo level).

The driver then ignores any drive

signals that may be subsequently

applied until the blocking time has

+15V

0V

IGBT

Gate

Voltage

-15V

+Vdc

IGBT

Collector

Voltage

Vth

0V

Response time

Fig. 5 Turn-on characteristic of an IGBT

elapsed. If no further drive signals are applied, the error information continues to be

stored in the LDI 001 even after the blocking time. The error memories can be erased

by briefly pulling the input VL/Reset to GND. However, these memories are also

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Description and Application Manual

erased automatically at the next edge change of the drive signal following the elapse

of the blocking time. The latter way of deleting the error memories is shown in Fig. 6.

The values of response and blocking times can be obtained from the data sheet of the

SCALE driver.

+VL

Input voltage

Gate voltage

0V

+15V

-15V

0A

Overcurrent turn-off threshold

Load current

Blocking time

(IGD 001)

Status output

(LDI 001)

0V

Blocking time (typically 1s)

t

0

1

t

= Power-transistor turn-off in case of overcurrent

0

t

- t = Blocking time (all input signals are ignored)

1

Fig. 6 Short circuit & overcurrent protection / Function of the blocking time

Power supply monitoring

An under-voltage monitoring circuit blocks the driver if the supply voltage drops to

below about 10…11V. In the case of under-voltage, the power semiconductor is

driven with a negative gate voltage and an error is reported.

The monitoring is performed locally on each gate driver (integrated in the IGD 001).

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Selecting the operating mode

Direct mode

In direct mode, there is no locking between the various drive channels. This allows the

use of regulators that already generate a dead time, for example. However, several

channels may also switch on concurrently, as is shown in the following example of an

asymmetrical half bridge.

+ DC Link

Channel 2

+VCC

C2

VCC (LDI)

MOD

Rth

Rg

1k

Rth2

IGD

Reset

VL/Reset

InB

G2

E2

PWM Input (15V Level)

+VCC +VCC

InA

LDI

Channel 1

15k

SO2

SO1

SO2

SO1

C1

Rth

Rg

Rth1

IGD

RC1

RC2

GND

G1

E1

GND

- DC Link

SCALE Driver Module

Fig. 7 Application example for direct mode: An asymmetrical half bridge

Legend to Fig. 7

Both channels are always driven simultaneously. For this reason, InA and InB are also

connected together. The input VL/Reset is connected to VCC via a pull-up resistor.

Inputs InA and InB are then programmed for a 15V level.

The MOD input is on VCC, so that direct mode is selected. RC1 and RC2 are

connected to GND. This is necessary in direct mode.

Both status outputs SO1 and SO2 are run back separately. In this way, the control

electronics can detect which channel shows an error status in any given case.

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+15V

PWM Input

0V

+15V

Gate G2

-15V

+15V

Gate G1

-15V

Fig. 8 Signals curves of the circuit as per Fig. 7

Half-bridge mode with dead time

In half-bridge mode, two channels are always operated as a half bridge. In this

mode, the SCALE driver can generate the required dead times directly in a range

from about 100ns up to several microseconds. Only two external RC networks are

required (see page 26 for dimensioning). All power semiconductors can be turned off

by switching the release input (InB) to low.

+VCC

+ DC Link

Channel 2

4k7

4V7

C2

VCC (LDI)

MOD

Rth

Rg

Rth2

IGD

GND

Reset

VL/Reset

InB

G2

E2

Enable (TTL)

PWM Input (TTL)

+VCC

InA

Inductive load

LDI

Channel 1

10k

15k

10k

SO2

SO1

C1

SO

Rth

Rg

Rth1

IGD

RC1

RC2

GND

G1

E1

100p

GND

- DC Link

SCALE Driver Module

Fig. 9 Application example for half-bridge mode with dead time generation

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Legend to Fig. 9

The power section represents the typical half-bridge circuit of a voltage link-circuit

inverter. Both IGBTs must never be driven simultaneously in this application.

Input MOD is on GND, which means that half-bridge mode has been selected.

Input InA is the PWM input, InB is the release input.

With the 4V7 zener diode at the VL/Reset input, the Schmitt triggers of inputs InA and

InB are programmed for TTL level.

The two status outputs SO1 and SO2 are connected together: there is a common error

acknowledgement for both drive channels.

RC1 and RC2 are each connected to an RC network 10kΩ/100 pF. This results in

dead times of about 500ns.

The circuit characteristics are shown in Fig. 10

+5V

0V

PWM Input

(InA)

+5V

0V

Enable

(InB)

Both channels go in OFF condition

+15V

Gate G2

Gate G1

-15V

+15V

-15V

Dead-Time (both channels OFF)

Fig. 10 Signals curves of the circuit as per Fig. 9

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Practical Part 1: the input side

The following terminal pins are normally led to the outside in the SCALE drivers:

Label

Description

GND

VDC

VDD

VL/Reset

MOD

InA

Power supply GND

Power supply +15V terminal for the DC/DC converter

Power supply +15V terminal for the interface electronic (LDI 001)

Define logic level/acknowledge error

Mode selection input

Input A, PWM 1 / PWM

InB

Input B, PMW 2 / Enable

SO1

SO2

RC1

Status output channel 1

Status output channel 2

RC networks for dead time channel 1

RC networks for dead time channel 2

RC2

Pin GND

Pin GND is connected to the ground of the electronic power supply. If several GNDs

are present, all GNDs should be connected to ground.

Pin VDC (voltage supply DC/DC converter)

A stabilized voltage supply of +15V with respect to GND is connected to terminal

VDC. This input supplies the internal DC/DC converter(s). The current consumption

and other data can be obtained from the data sheet of the relevant driver. It is

recommended that a blocking capacitor is inserted between VDC and GND.

Pin VDD (voltage supply electronics input side)

A stabilized voltage supply of +15V with respect to GND is connected to terminal

VDD. Additional data may be obtained from the data sheet of the relevant driver.

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Pin VL / Reset (define logic level/acknowledge error)

This terminal is used for programming the switching thresholds of Schmitt trigger

inputs InA and InB. These inputs switch on at 2/3 of the voltage applied to VL. A level

of 1/3 of this voltage acts as a turn-off signal.

+15V

R1

1k

4k7

(optional)

Q1

VL/Reset

(optional)

VL/Reset

1 = Reset

D1

4V7

Q1

GND

Fig. 11 Circuit for input VL/Reset for 5V logic (left) and 15V logic level

When the PWM signals have TTL level, pin VL is connected as shown in Fig. 11 (left).

When the signals at inputs InA and InB have 15V level, then pin VL should be

connected via a resistor of about 1kΩ to +15V (see Fig. 11 (right)). The switching

thresholds of Schmitt trigger inputs InA and InB are then 5V and 10V respectively. This

variant is recommended especially in the case of longer connecting cables between

the control electronics and the driver; this produces higher signal-to-noise ratios.

In addition, the input VL has a double function: if it is pulled to GND (see Transistor

Q1 in Fig. 11), the error memories of the LDI 001 are erased when they were

previously set.

The current consumption of the inputs VL is (depending on the switching status and per

LDI 001):

typ. 0.14...0.5mA @ 5V

typ. 0.4...1.4 mA @ 15V

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Note:

When a SCALE driver is turned on, the error memories are usually set. They can be

erased by pulling pin VL to GND after turn-on or during the entire turn-on process (for

example by a power-up reset signal). However, the error memories are also erased

automatically at the first edge of a drive signal after the blocking time has elapsed

(see also Fig. 6).

Important notes:

The VL/Reset input has no Schmitt trigger characteristic like signal inputs InA and InB.

For this reason, only “clean” digital levels are permissible. Voltages smaller than 1V

are regarded as a reliable level indicator for the error reset function. Voltages

between 4V and 15V are regarded as safe logic levels. Levels between 1V and 4V

must be avoided.

Pin MOD (mode selection)

The input mode selection “MOD” can be used to select the operating mode of the

LDI 001.

If the MOD pin is connected to GND, half-bridge mode is selected. In this operating

mode, inputs RC1 and RC2 must be connected to RC networks. For the dimensioning,

see Section “Pin RCx (RC networks for the dead times)” from page 26 onwards.

In half-bridge mode, inputs InA and InB have the following functions: InA is the PWM

input and InB has the release function.

If the level on InB is “Lo”, then both channels are blocked. With a Hi level on InB, the

outputs are released, depending on InA. In the event of an edge change from Lo to Hi

at InA, channel 1 switches off immediately and channel 2 switches on when the dead

time has elapsed. In the event of an edge change from Hi to Lo at InA, channel 2 is

immediately switched off and channel 1 is switched on when the dead time has

elapsed. The characteristic is shown in Fig. 10.

If the MOD pin is connected to VCC, direct mode is selected. In this operating mode,

there is no mutual influence between the two drive channels. InA affects channel 1

and InB affects channel 2. In each case, a high level at the input leads to switch-on of

the corresponding IGBT. This operating mode should be selected when the control

electronics has already generated the dead times and a control signal is thus present

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Description and Application Manual

for each power semiconductor. Moreover, in this operating mode both channels can

also be driven either simultaneously or in overlapping mode.

Note:

In direct mode, the two pins RC1 and RC2 are connected to GND. If this is not done,

unexpected switching processes will result.

Pin InA (signal input A)

In direct mode, terminal InA drives channel 1 directly. The input has a Schmitt trigger

characteristic and corresponds to positive logic: a Hi level switches the power

semiconductor on, a Lo level means a switch-off state.

In half-bridge mode, the PWM signal for the phase branch is connected to InA (see

also “Pin MOD” from page 24 onwards).

Inputs InA and InB can be operated with 5V...15V levels (see also “Pin VL/Reset”

from page 23 onwards).

During the build-up of the supply voltage, both inputs InA and InB or input VL/Reset

should be on GND, so that no uncontrolled drive signals are generated.

Pin InB (signal input B)

In direct mode, terminal InB controls channel 2 directly. The input has a Schmitt

trigger characteristic and corresponds to positive logic (like InA).

In half-bridge mode, the release signal for the phase branch is connected to InB. Hi

level means release, Lo level means that all channels are blocked (see also “Pin

MOD” from page 24 onwards).

Pin SOx (status outputs)

The “x” in “SOx” stands for the number of the drive channel in multi-channel drivers.

The output stage SOx consists of an open-collector transistor (see Fig. 3). The output is

pulled to GND if an error has been detected in channel x. The transistor goes high

when no error is present.

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Any number of status outputs can be connected together directly if a common error

signal is required for each phase or current inverter (see the examples in Fig. 1 and

Fig. 9).

The status outputs can be pulled to +5V...+15V via a pull-up resistor. A current of

1.5mA can be applied to the outputs SOx.

How the status information is determined

Every time that an edge of a drive signal changes:

a)

b)

c)

the error memory in the LDI 001 is erased (for each channel),

the status information of the IGD 001 is transferred to the LDI 001,

if an error was detected in the IGD 001 (and the blocking time is still running),

then the error memory in the LDI 001 is set (and the output is pulled to GND).

Note:

The error memory can also be erased when VL is pulled to GND (see “Pin VL”). The

error memory is then reset at the next edge change as long as there is still an error in

this channel.

Pin RCx (RC networks for the dead times)

The “x” in “RCx” stands for the number of the drive channel in multi-channel drivers

In half-bridge mode, an RC network is connected to each RCx terminal. It determines

the dead time of the corresponding channel.

Table for values of the dead times of RC networks:

R

C

typ. dead time

£ 200ns

10k

15k

22k

33k

47pF

100pF

120pF

150pF

220pF

£ 500ns

£ 1.1ms

£ 2.1ms

£ 4.6ms

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These values produce the smallest scatter of dead times over the whole temperature

range. Resistance values below 5kΩ are not permissible.

The RC networks must be connected as shown in Fig. 9: the resistor is connected to

VCC, the capacitor to GND.

In direct mode, all RC inputs must be connected to GND.

Practical Part 2: the power side

In the SCALE drivers, the terminal pins described below are usually accessible from the

outside:

Pin Gx (gate terminal)

The “x” in “Gx” stands for the number of the drive channel in multi-channel drivers.

The output Gx is the output for the gate drive. When the SCALE driver is supplied with

15V, the gate is driven with 15V. The negative gate voltage is generated internally.

A sufficiently low-resistance termination of the gate is ensured by the SCALE driver

even if it is not supplied with the operating voltage.

The maximum permissible gate current can be obtained from the data sheet of the

SCALE driver used. For the correct selection and calculation of drivers, reference is

made to Application Document AN-9701 from CONCEPT “IGBT drivers correctly

calculated”.

In order to allow the

switching speed to be set

independently during both

turn-on and turn-off, a gate

SCALE Driver

circuit can be used with two

G

gate resistors and a diode

(see Fig. 12).

E

Fig. 12 Asymmetrical gate resistors

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Pin Ex (emitter terminal)

The “x” in “Ex” stands for the number of the drive channels in multi-channel drivers.

This terminal should be connected to the emitter or source terminal of the power

transistor. The connection must be as short as possible and be run directly to the

emitter or source terminal of the power element. This terminal should be used in

modules with auxiliary emitters or an auxiliary source. This terminal is also used as the

low end of the reference resistor Rthx. Where possible, this should be connected

directly to the terminal Ex of the driver.

Pin Cx (collector sense)

The “x” in “Cx” stands for the number of the drive channels in multi-channel drivers.

This terminal is used to measure the voltage drop across the turned-on power transistor

in order to ensure protection from short circuit and overload. It should be noted that it

V+

1,4mA

150uA

Dm (2 x 1N4007)

Rm

Ca

4

5

Cx

OVERCURRENT

MEASURING

5WK[

RGx

Rthx

Gx

IGD 001

SCALE Driver Module

Ex

Fig. 13 Principle of the collector sense circuit

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must never be connected directly to the drain or collector of the power transistor. A

circuit with a high-blocking diode (Dm) must be included to protect the measuring

terminal from the high drain or collector voltage of the turned-off power element. For

1200V and 1700V modules, a circuit made up of two or three diodes of type

1N4007 connected in series has proved its worth in place of exotic higher-blocking

elements (see Fig. 13). It is recommended that the voltage of these diodes be over-

dimensioned by at least 40%. Fast diodes are not required here. Standard line diodes

are quite sufficient.

A current source integrated in the IGD 001 ensures that a current flows through the

diode(s) in the power semiconductors when the power transistor is turned on. A

voltage is thus applied at the comparator that corresponds to the forward voltage of

the turned-on transistor plus the diode forward voltage and the voltage drop across

Rm (about 250 mV).

It should be noted that power transistors take a finite time to turn on, especially in the

case of IGBTs, that can take several microseconds to completely switch through. The

current source and the capacitor (Ca) cause a delay in the measurement after the

power transistor has been turned on. This delay is known as the response time. Its

magnitude as a function of the turn-off threshold can be obtained from the data sheet

of the selected SCALE driver.

Negative voltages are impermissible at the input Cx.

Pin Rthx (reference resistor)

The “x” in “Rthx” stands for the number of the drive channels in multi-channel drivers.

A resistor is connected to this pin as a reference. It defines the maximum voltage drop

across the turned-on power transistor at which the protection function of the drive

circuit is activated and thus the power transistor is turned off.

The protection function is always active when the voltage at Cx (measurement

drain/collector) exceeds the voltage at Rthx. Ex is the reference potential. The

reference resistor must be placed as close as possible to the driver module.

The current source in the SCALE driver supplies a current of 150µA.

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The reference resistor can be calculated as follows:

Vth

Rth =

150µA

Vth = turn-off threshold

Example: required turn-off threshold Vth = 5.85V

Vth

5.85V

Rth =

=

= 39kW

150µA

Note:

Because of the voltage drops across the diode Dm (approx. 0.6 V per diode) and the

resistor Rm (approx. 250 mV) in the collector sense circuit, the voltage at the power

semiconductor – at which the protection function cuts in – is lower than the threshold

calculated above by about 850mV with a diode (or 1.45V if two diodes are

connected in series). In this example with two diodes connected in series, the

protection function thus reacts when the collector voltage exceeds a value of 4.4V

(5.85V-1.45V).

Layout and wiring

Drivers should as a rule be

placed as close as possible to

the power semiconductors so

SCALE Driver

C2

that the leads from the driver to

the transistors are as short as

possible. Lead lengths of more

than 10 cm must be avoided.

G2

15V

E2

twisted wires

max. 10cm

When

the

power

C1

G1

E1

semiconductors are connected

by stranded wires, it is

recommended always to twist

the three associated leads Gx,

Ex, and Cx (see Fig. 14).

15V

Power GND

It is also recommended to place

two

15V

zener

diodes

Fig. 14 Wiring driver Ð IGBT

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connected in counter-series immediately between the gate and emitter of the IGBTs

(see Fig. 14). This prevents the gate voltage from increasing to an impermissible level

due to parasitic effects (such as the Miller effect). An excessive gate voltage increases

the short-circuit current to an over-proportional extent and can lead to destruction of

the power semiconductor.

The really fast variant: evaluation boards

CONCEPT offers a wide range of evaluation boards to introduce users quickly to the

sector of IGBT technology and to the protection concept used with SCALE drivers.

These boards represent completely built up and tested current-inverter circuits in the

power range from 10 kW to over 1000 kW and contain the power semiconductors

(IGBTs), a driver card with correctly matched drivers and the link-circuit capacitors.

The power sections are designed with very low inductance.

Together with the documentation supplied, these evaluation boards can be used to

create prototype equipment that is ready to use within a matter of hours. You are

invited to request an overview of the available evaluation boards.

If you need any help, simply call our technical support

CONCEPT offers you expert help for your questions and problems:

E-Mail: support@ct-concept.com or on the Internet: www.CT-CONCEPT.com

Fax international ++41 32 / 322 22 51 (in Switzerland: 032 / 322 22 51)

Tel international ++41 32 / 322 42 36 (in Switzerland: 032 / 322 42 36)

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Important information: the SCALE driver data sheets

A data sheet is available for every SCALE driver.

Please request our overview of SCALE drivers.

Quite special: customized SCALE drivers

If you need a power MOSFET or IGBT driver that is not included in the delivery range,

don’t hesitate to contact CONCEPT or your CONCEPT sales partner.

CONCEPT engineers have more than 15 years experience in the development and

manufacture of intelligent drivers for power MOSFETs and IGBTs and have already

implemented a large number of customized solutions.

Exclusion Clause

CONCEPT reserves the right to make modifications to its technical data and product

specifications at any time without prior notice. The general terms and conditions of

delivery of CT-Concept Technology Ltd. apply.

Manufacturer

Your Distribution Partner

CT-Concept Technology Ltd.

Intelligent Power Electronics

Renferstrasse 15

CH-2504 Biel-Bienne

(Switzerland)

Phone ++41 - 32 - 341 41 01

Fax ++41 - 32 - 341 71 21

E-Mail info@ct-concept.com

Internet www.CT-CONCEPT.com

Internet www.IGBT-Driver.com

We reserve the right to make any technical modifications without prior notice.

Version from 26.05.99

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型号：	2SC0108T2A0-17
厂家：	ETC
描述：	DESCRIPTION AND APPLICATION MANUAL FOR SCALE DRIVERS 描述与应用手册SCALE驱动程序驱动
文件：	总32页 (文件大小：511K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

2SC0108T2A0-17 [ETC]

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