IL4108-X017_技术文档

IL410, IL4108

Vishay Semiconductors

Optocoupler, Phototriac Output, Zero Crossing,

High dV/dt, Low Input Current

FEATURES

• High input sensitivity

1

6

5

4

MT2

A

C

2

3

NC

• I_FT= 2 mA, PF = 1.0

ZCC*

NC

MT1

• I_FT= 5 mA, PF 1.0

*Zero crossing circuit

i179030_4

21842-1

V

D

E

• 300 mA on-state current

• Zero voltage crossing detector

• 600 V, 800 V blocking voltage

• High static dV/dt 10 kV/μs

• Very low leakage < 10 A

• Isolation test voltage 5300 V_RMS

• Small 6 pin DIP package

DESCRIPTION

The IL410 and IL4108 consists of a GaAs IRLED optically

coupled to a photosensitive zero crossing TRIAC network.

The TRIAC consists of two inverse parallel connected

monolithic SCRs. These three semiconductors are

assembled in a six pin dual in-line package.

High input sensitivity is achieved by using an emitter

follower phototransistor and a cascaded SCR predriver

resulting in an LED trigger current of less than 2 mA (DC).

The use of a proprietary dV/dt clamp results in a static dV/dt

of greater than 10 kV/ms. This clamp circuit has a MOSFET

that is enhanced when high dV/dt spikes occur between

MT1 and MT2 of the TRIAC. When conducting, the FET

clamps the base of the phototransistor, disabling the first

stage SCR predriver.

• Compliant to RoHS Directive 2002/95/EC and in

accordance to WEEE 2002/96/EC

APPLICATIONS

• Solid-state relays

• Industrial controls

• Office equipment

• Consumer appliances

The zero cross line voltage detection circuit consists of two

enhancement MOSFETS and a photodiode. The inhibit

voltage of the network is determined by the enhancement

voltage of the N-channel FET. The P-channel FET is enabled

by a photocurrent source that permits the FET to conduct

the main voltage to gate on the N-channel FET. Once the

main voltage can enable the N-channel, it clamps the base

of the phototransistor, disabling the first stage SCR

predriver.

AGENCY APPROVALS

• UL1577, file no. E52744 system code H, double protection

The 600 V, 800 V blocking voltage permits control of off-line

voltages up to 240 V_AC, with a safety factor of more than

• CSA 93751

two, and is sufficient for as much as 380 V_AC

.

• DIN EN 60747-5-2 (VDE 0884)/DIN EN 60747-5-5

(pending), available with option 1

The IL410, IL4108 isolates low-voltage logic from 120 V_AC

,

240 V_AC, and 380 V_AClines to control resistive, inductive, or

capacitive loads including motors, solenoids, high current

thyristors or TRIAC and relays.

ORDERING INFORMATION

DIP-#

I

L

4

1

0

#

-

X

0

#

T

7.62 mm

Option 6

Option 7

PART NUMBER

PACKAGE OPTION

TAPEAND

REEL

10.16 mm

Option 8

> 0.7 mm

Option 9

9.27 mm

> 0.1 mm

AGENCY CERTIFIED/PACKAGE

UL

BLOCKING VOLTAGE V_DRM(V)

600

800

DIP-6

IL410

IL4108

DIP-6, 400 mil, option 6

SMD-6, option 7

SMD-6, option 8

SMD-6, option 9

VDE, UL

IL410-X006

IL410-X007T ⁽¹⁾

IL410-X008T

IL410-X009T ⁽¹⁾

600

IL4108-X006

IL4108-X007T ⁽¹⁾

-

IL4108-X009T ⁽¹⁾

800

DIP-6

IL410-X001

IL410-X016

IL410-X017

IL410-X019T ⁽¹⁾

IL4108-X001

IL4108-X016

IL4108-X017

-

DIP-6, 400 mil, option 6

SMD-6, option 7

SMD-6, option 9

Note

(1)

Also available in tubes, do not put T on the end.

Document Number: 83627

Rev. 2.0, 29-Mar-11

For technical questions, contact: optocoupleranswers@vishay.com

This document is subject to change without notice.

www.vishay.com

1

THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000

IL410, IL4108

Vishay Semiconductors

Optocoupler, Phototriac Output, Zero Crossing,

High dV/dt, Low Input Current

ABSOLUTE MAXIMUM RATINGS (T_amb= 25 °C, unless otherwise specified)

PARAMETER

TEST CONDITION

PART

SYMBOL

VALUE

UNIT

INPUT

Reverse voltage

Forward current

Surge current

Power dissipation

Derate from 25 °C

OUTPUT

V_R

I_F

6

V

mA

60

I_FSM

P_diss

2.5

100

1.33

A

mW

mW/°C

IL410

V_DRM

I_TM

600

800

300

3

V

Peak off-state voltage

IL4108

RMS on-state current

Single cycle surge current

Total power dissipation

Derate from 25 °C

COUPLER

mA

A

P_diss

500

6.6

mW

mW/°C

Isolation test voltage

between emitter and detector

t = 1 s

V_ISO

5300

V_RMS

Pollution degree (DIN VDE 0109)

Creepage distance

2

 7

mm

Clearance distance

Comparative tracking index per

DIN IEC112/VDE 0303 part 1, group IIIa

per DIN VDE 6110

CTI

 175

V

_IO= 500 V, T_amb= 25 °C

R_IO

 10¹²

 10¹¹



Isolation resistance

V_IO= 500 V, T_amb= 100 °C

Storage temperature range

Ambient temperature

T_stg

T_amb

- 55 to + 150

- 55 to + 100

°C

max. 10 s dip soldering

 0.5 mm from case bottom

Soldering temperature ⁽¹⁾

T_sld

260

°C

Notes

•

Stresses in excess of the absolute maximum ratings can cause permanent damage to the device. Functional operation of the device is not

implied at these or any other conditions in excess of those given in the operational sections of this document. Exposure to absolute

maximum ratings for extended periods of the time can adversely affect reliability.

Refer to reflow profile for soldering conditions for surface mounted devices (SMD). Refer to wave profile for soldering conditions for through

hole devices (DIP).

(1)

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For technical questions, contact: optocoupleranswers@vishay.com

This document is subject to change without notice.

Document Number: 83627

Rev. 2.0, 29-Mar-11

THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000

IL410, IL4108

Vishay Semiconductors

Optocoupler, Phototriac Output, Zero Crossing,

High dV/dt, Low Input Current

ELECTRICAL CHARACTERISTICS (T_amb= 25 °C, unless otherwise specified)

PARAMETER

TEST CONDITION

PART

SYMBOL

MIN.

TYP.

MAX.

UNIT

INPUT

Forward voltage

Reverse current

Input capacitance

Thermal resistance, junction to ambient

OUTPUT

I_F= 10 mA

V_F

I_R

1.16

0.1

1.35

10

V

μA

V

_R= 6 V

V_F= 0 V, f = 1 MHz

C_IN

R_thja

25

pF

750

°C/W

V

_D= V_DRM, T_amb= 100 °C,

I_F= 0 mA

Off-state current

I_DRM

10

100

μA

On-state voltage

I_T= 300 mA

f = 50 Hz

V_TM

I_TSM

I_FT1

1.7

3

2

V

A

Surge (non-repetitive), on-state current

Trigger current 1

V

_D= 5 V

_D= 220 V_RMS, f = 50 Hz,

T_j= 100 °C, t_pIF> 10 ms

mA

V

Trigger current 2

I_FT2

6

mA

I_FT1/T_j

I_FT2/T_j

V_DINH/T_j

I_DINH

7

14

μA/°C

mV/°C

μA

Trigger current temp. gradient

Inhibit voltage temp. gradient

Off-state current in inhibit state

Holding current

- 20

50

65

I_F= I_FT1, V_D= V_DRM

200

500

25

I_H

μA

Latching current

V_T= 2.2 V

I_L

μA

Zero cross inhibit voltage

I_F= rated I_FT

V_IH

15

V

_D= 0.67 V_DRM, T_j= 25 °C

_D= 0.67 V_DRM, T_j= 80 °C

dV/dt_cr

10 000

5000

V/μs

Critical rate of rise of off-state voltage

V

_D= 230 V_RMS

,

dV/dt_crq

8

7

V/μs

I

_D= 300 mA_RMS, T_J= 25 °C

Critical rate of rise of voltage at current

commutation

V

_D= 230 V_RMS

,

_D= 300 mA_RMS, T_J= 85 °C

Critical rate of rise of on-state current

commutation

V

_D= 230 V_RMS

,

dI/dt_crq

R_thja

12

A/ms

°C/W

_D= 300 mA_RMS, T_J= 25 °C

Thermal resistance, junction to ambient

150

COUPLER

Critical rate of rise of coupled

input/output voltage

I_T= 0 A, V_RM= V_DM= V_DRM

f = 1 MHz, V_IO= 0 V

dV_IO/dt

10 000

V/μs

Common mode coupling capacitance

Capacitance (input to output)

C_CM

C_IO

R_IO

0.01

0.8

 10¹²

 10¹¹

pF



V

_IO= 500 V, T_amb= 25 °C

Isolation resistance

V

_IO= 500 V, T_amb= 100 °C



Note

•

Minimum and maximum values are testing requirements. Typical values are characteristics of the device and are the result of engineering

evaluation. Typical values are for information only and are not part of the testing requirements.

SWITCHING CHARACTERISTICS (T_amb= 25 °C, unless otherwise specified)

PARAMETER

TEST CONDITION

PART

SYMBOL

MIN.

TYP.

MAX.

UNIT

Turn-on time

V_RM= V_DM= V_DRM

t_on

35

μs

Document Number: 83627

Rev. 2.0, 29-Mar-11

For technical questions, contact: optocoupleranswers@vishay.com

This document is subject to change without notice.

www.vishay.com

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THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000

IL410, IL4108

Vishay Semiconductors

Optocoupler, Phototriac Output, Zero Crossing,

High dV/dt, Low Input Current

TYPICAL CHARACTERISTICS (T_amb= 25 °C, unless otherwise specified)

10³

1.4

5

1.3

T

= - 55 °C

= 25 °C

A

T_j= 25 °C

100 °C

1.2

10²

5

I_T= f(V_T),

Parameter: T_j

A

1.1

1.0

10¹

5

0.9

0.8

0.7

T

= 85 °C

A

10⁰

0.1

1

10

100

0

1

2

3

4

V_T(V)

iil410_06

I_F- Forward Current (mA)

iil410_03

Fig. 4 - Typical Output Characteristics

Fig. 1 - Forward Voltage vs. Forward Current

10 000

400

300

200

100

0

τ

I

R

= f(V ),

T

= 150 K/W

TRMS

thJA

Duty Factor

Device switch

soldered in pcb

or base plate.

0.005

0.01

0.02

0.05

0.1

1000

t

τ

DF = /t

0.2

100

10

0.5

10^-610^-510^-410^-310^-210^-110⁰10¹

0

20

40

60

80

100

T_A(°C)

iil410_07

iil410_04

t - LED Pulse Duration (s)

Fig. 5 - Current Reduction

Fig. 2 - Peak LED Current vs. Duty Factor, 

150

100

400

300

200

100

0

50

0

I

= f(T

), R

PIN5

= 16.5 K/W

thJ-PIN5

TRMS

Thermocouple measurement must

be performed potentially separated

to A1 and A2. Measuring junction

as near as possible at the case.

- 60 - 40 - 20

0

20 40 60 80 100

50

60

70

80

90

100

T_PIN5(°C)

iil410_08

iil410_05

T_A- Ambient Temperature (°C)

Fig. 6 - Current Reduction

Fig. 3 - Maximum LED Power Dissipation

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For technical questions, contact: optocoupleranswers@vishay.com

This document is subject to change without notice.

Document Number: 83627

Rev. 2.0, 29-Mar-11

THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000

IL410, IL4108

Vishay Semiconductors

Optocoupler, Phototriac Output, Zero Crossing,

High dV/dt, Low Input Current

10³

0.6

t_gd= f (I_F/I_FT25 °C), V_D= 200 V

f = 40 to 60 Hz, Parameter: T_j

40 to 60 Hz

Line operation,

P_tot= f(I_TRMS

0.5

0.4

0.3

)

10²

5

T_j= 25 °C

100 °C

0.2

0.1

0

10¹

10⁰

5

10¹

5

10²

0

100

I_TRMS(mA)

200

300

iil410_09

I_F/I_{FT25 °C}

iil410_11

Fig. 7 - Typical Trigger Delay Time

Fig. 9 - Power Dissipation 40 Hz to 60 Hz Line Operation

10³

12

T_j= 25 °C

100 °C

V

T_j= 25 °C

100 °C

10

10²

5

8

6

4

V

= f (I /I 25°C),

FT

DINH min

parameter: T

F

10¹

5

j

Device zero voltage

switch can be triggered

only in hatched are

I_DINH= f(I_F/I_FT25 °C),

V_D= 600 V, Parameter:T_j

below T curves.

j

10⁰

0

2

4

6

8

10 12 14 16 18 20

10⁰

5

10¹

5

10²

I_F/I_{FT25 °C}

iil410_10

I_F/I_{FT25 °C}

iil410_12

Fig. 10 - Typical Static Inhibit Voltage Limit

Fig. 8 - Off-State Current in Inhibited State vs. I_F/I_FT25 °C

TRIGGER CURRENT VS. TEMPERATURE AND VOLTAGE

The trigger current of the IL410, 4108 has a positive

temperature gradient and also is dependent on the terminal

voltage as shown as the fig. 11.

For the operating voltage 250 V_RMSover the temperature

range - 40 °C to 85 °C, the I_Fshould be at least 2.3 x of the

I_FT1(2 mA, max.).

Considering - 30 % degradation over time, the trigger

current minimum is I_F= 2 x 2.3 x 130 % = 6 mA

3.5

3.0

100 °C

2.5

85 °C

2.0

1.5

25 °C

50 °C

1.0

0.5

0.0

0

50

100 150 200 250 300 350

V_RMS(V)

21602

Fig. 11 - Trigger Current vs.

Temperature and Operating Voltage (50 Hz)

Document Number: 83627

Rev. 2.0, 29-Mar-11

For technical questions, contact: optocoupleranswers@vishay.com

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This document is subject to change without notice.

THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000

IL410, IL4108

Vishay Semiconductors

Optocoupler, Phototriac Output, Zero Crossing,

High dV/dt, Low Input Current

INDUCTIVE AND RESISTIVE LOADS

For inductive loads, there is phase shift between voltage and current, shown in the fig. 12.

I_F(on)

I_F(off)

AC line

voltage

AC line

voltage

AC current

through

triac

AC current

through

triac

Commutating dV/dt

Voltage

across triac

21607

Resistive load

Inductive load

Fig. 12 - Waveforms of Resistive and Inductive Loads

The voltage across the triac will rise rapidly at the time the

current through the power handling triac falls below the

holding current and the triac ceases to conduct. The rise

rate of voltage at the current commutation is called

commutating dV/dt. There would be two potential problems

for ZC phototriac control if the commutating dV/dt is too

high. One is lost control to turn off, another is failed to keep

the triac on.

1

0.1

C

(µF) = 0.0032 (µF)*10^0.0066 I (mA)

L

s

T

= 25 °C, PF = 0.3

= 2.0 mA

A

Lost control to turn off

0.01

0.001

I

F

If the commutating dV/dt is too high, more than its critical

rate (dV/dt_crq), the triac may resume conduction even if the

LED drive current I_Fis off and control is lost.

0

50 100 150 200 250 300 350 400

I_L- Load Current (mA_RMS

In order to achieve control with certain inductive loads of

power factors is less than 0.8, the rate of rise in voltage

(dV/dt) must be limited by a series RC network placed in

parallel with the power handling triac. The RC network is

called snubber circuit. Note that the value of the capacitor

increases as a function of the load current as shown in fig. 13.

iil410_01

)

Fig. 13 - Shunt Capacitance vs. Load Current

2.0

I

Normalized to I

at PF = 1.0

Fth

Failed to keep on

T

= 25 °C

1.8

1.6

1.4

1.2

A

As a zero-crossing phototriac, the commutating dV/dt

spikes can inhibit one half of the TRIAC from keeping on If

the spike potential exceeds the inhibit voltage of the zero

cross detection circuit, even if the LED drive current I_Fis on.

This hold-off condition can be eliminated by using a snubber

and also by providing a higher level of LED drive current. The

higher LED drive provides a larger photocurrent which

causes the triac to turn-on before the commutating spike

has activated the zero cross detection circuit. Fig. 14 shows

the relationship of the LED current for power factors of less

than 1.0. The curve shows that if a device requires 1.5 mA

for a resistive load, then 1.8 times (2.7 mA) that amount

would be required to control an inductive load whose power

factor is less than 0.3 without the snubber to dump the

spike.

1.0

0.8

0.0

0.2

0.4

0.6

0.8

1.0

1.2

iil410_02

PF - Power Factor

Fig. 14 - Normalized LED Trigger Current vs. Power Factor

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For technical questions, contact: optocoupleranswers@vishay.com

Document Number: 83627

Rev. 2.0, 29-Mar-11

This document is subject to change without notice.

THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000

IL410, IL4108

Vishay Semiconductors

Optocoupler, Phototriac Output, Zero Crossing,

High dV/dt, Low Input Current

Indirect switching operation:

APPLICATIONS

Direct switching operation:

The IL410, IL4108 switch acts here as an isolated driver and

thus enables the driving of power thyristors and power triacs

by microprocessors. Fig. 16 shows a basic driving circuit of

inductive load. The resister R1 limits the driving current

pulse which should not exceed the maximum permissible

surge current of the IL410, IL4108. The resister R_Gis needed

only for very sensitive thyristors or triacs from being

triggered by noise or the inhibit current.

The IL410, IL4108 isolated switch is mainly suited to control

synchronous motors, valves, relays and solenoids. Fig. 15

shows a basic driving circuit. For resistive load the snubber

circuit R_SC_Scan be omitted due to the high static dV/dt

characteristic.

IL410

1

2

3

6

5

4

Hot

Control

R_S

IL410

R1

360

220/240

VAC

Hot

1

2

3

6

5

4

C_S

ZC

Control

220/240

VAC

R_S

U1

ZC

Inductive load

Nutral

21608

C_S

R_G

330

Inductive load

U1

Nutral

Fig. 15 - Basic Direct Load Driving Circuit

21609

Fig. 16 - Basic Power Triac Driver Circuit

PACKAGE DIMENSIONS in millimeters

Pin one ID

3

2

1

6

6.30

6.50

ISO method A

4

5

8.50

8.70

7.62 typ.

1.22

1.32

1 min.

3.30

3.81

4° typ.

18°

3.30

3.81

0.84 typ.

3° to 9°

0.20

0.30

0.46

0.51

0.84 typ.

2.54 typ.

7.62 to 8.81

i178014

Document Number: 83627

Rev. 2.0, 29-Mar-11

For technical questions, contact: optocoupleranswers@vishay.com

This document is subject to change without notice.

www.vishay.com

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THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000

IL410, IL4108

Vishay Semiconductors

Optocoupler, Phototriac Output, Zero Crossing,

High dV/dt, Low Input Current

Option 7

Option 8

Option 6

Option 9

10.3 max.

7.62 typ.

0.7 min.

0.25 0.1

0.1 0.1

0.6 min.

3.6 0.3

3.5 0.3

4.3 0.3

0.6 min.

0.1 min.

9.27 min.

12.1 max.

8 min.

2.55 0.25

10.3 max.

8 min.

10.16 typ.

0.76

1.78

0.76

R 0.25

2.54

1.78

1.52

1.78

1.52

20802-25

8 min.

11.05

1.52

8 min.

11.05

8 min.

11.05

PACKAGE MARKING (example)

IL4108

V YWW H 68

Notes

•

Only options 1, 7, and 8 are reflected in the package marking.

The VDE Logo is only marked on option 1 parts.

Tape and reel suffix (T) is not part of the package marking.

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For technical questions, contact: optocoupleranswers@vishay.com

This document is subject to change without notice.

Document Number: 83627

Rev. 2.0, 29-Mar-11

THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000

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Disclaimer

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Statements regarding the suitability of products for certain types of applications are based on Vishay's knowledge of typical

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about the suitability of products for a particular application. It is the customer's responsibility to validate that a particular product

with the properties described in the product specification is suitable for use in a particular application. Parameters provided in

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parameters, including typical parameters, must be validated for each customer application by the customer's technical experts.

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Revision: 09-Jul-2021

Document Number: 91000

1


型号：	IL4108-X017
厂家：	VISHAY
描述：	OPTOISOLATOR 5.3KV TRIAC 三端双向交流开关
文件：	总9页 (文件大小：170K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

IL4108-X017 [VISHAY]

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