MOC3052V-M Fairchild Semiconductor, MOC3052V-M Datasheet - Page 5

MOC3052V-M

Manufacturer Part Number

MOC3052V-M

Description

Optocoupler

Manufacturer

Fairchild Semiconductor

Datasheet

1.MOC3052V-M.pdf (11 pages)

Specifications of MOC3052V-M

No. Of Channels

Optocoupler Output Type

Phototriac

Input Current

10mA

Output Voltage

600V

Opto Case Style

DIP

No. Of Pins

Peak Reflow Compatible (260 C)

Yes

Isolation Voltage

7.5kV

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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MOC3051-M

0.9

0.8

0.7

0.6

0.5

0.4

0.3

0.2

0.1

1.5

1.4

1.3

1.2

1.1

0.9

0.8

0.7

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0.5

0.001

- 40

Figure 5. Minimum Time for LED Turn–Off to Zero

Figure. 6 Holding Current, I

Figure. 8 LED Trigger Current, I

- 30 - 20 -10 0

0ϒ

0.01

T A , AMBIENT TEMPERATURE (

Cross of AC Trailing Edge

0.1

180°

dv/dt (V/ µs)

LED PW

LED TURN OFF MIN 200 µs

NORMALIZED TO:

vs. Temperature

100

AC SINE

I FT at 3 V

LED CURRENT

vs. dv/dt

1000

10000

Page 5 of 11

OPTOISOLATORS TRIAC DRIVERS

Minimum LED Off Time in Phase Control

Applications

In Phase control applications one intends to be able to control

each AC sine half wave from 0 to 180 degrees. Turn on at zero

degrees means full power and turn on at 180 degree means

zero power. This is not quite possible in reality because triac

driver and triac have a ﬁxed turn on time when activated at

zero degrees. At a phase control angle close to 180 degrees

the driver’s turn on pulse at the trailing edge of the AC sine

wave must be limited to end 200 ms before AC zero cross as

shown in Figure 5. This assures that the triac driver has time

to switch off. Shorter times may cause loss of control at the

following half cycle.

Triac drivers with good noise immunity (dv/dt static) have inter-

nal noise rejection circuits which prevent false triggering of the

device in the event of fast raising line voltage transients. Induc-

tive loads generate a commutating dv/dt that may activate the

triac drivers noise suppression circuits. This prevents the

device from turning on at its speciﬁed trigger current. It will in

this case go into the mode of “half waving” of the load. Half

waving of the load may destroy the power triac and the load.

Figure 8 shows the dependency of the triac drivers I

the reapplied voltage rise with a Vp of 400 V. This dv/dt condi-

tion simulates a worst case commutating dv/dt amplitude.

It can be seen that the I

ing dv/dt reaches 1000 V/ms. The data sheet speciﬁed I

therefore applicable for all practical inductive loads and load

factors.

versus dv/dt

10000

1000

100

0.1

6-PIN DIP RANDOM-PHASE

-40

Figure. 7 Leakage Current, I

-20

T A , AMBIENT TEMPERATURE (

does not change until a commutat-

(600 VOLT PEAK)

MOC3052-M

DRM

vs. Temperature

6/15/05

versus

100

MOC3052V-M Fairchild Semiconductor, MOC3052V-M Datasheet - Page 5

MOC3052V-M

Specifications of MOC3052V-M

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