ACPL-W314-500E Avago Technologies US Inc., ACPL-W314-500E Datasheet - Page 11

ACPL-W314-500E

Manufacturer Part Number

ACPL-W314-500E

Description

OPTOCOUPLER IGBT 0.4A 6-SOIC

Manufacturer

Avago Technologies US Inc.

Datasheets

1.ACPL-P314-500E.pdf (14 pages)

2.ACPL-W314-060E.pdf (13 pages)

Specifications of ACPL-W314-500E

Output Type

Push-Pull, Totem-Pole

Package / Case

6-SOP

Voltage - Isolation

3750Vrms

Number Of Channels

1, Unidirectional

Current - Output / Channel

600mA

Propagation Delay High - Low @ If

300ns @ 7mA

Current - Dc Forward (if)

25mA

Input Type

Mounting Type

Surface Mount

Fall Time

50 ns

Rise Time

50 ns

Configuration

1 Channel

Isolation Voltage

3750 Vrms

Maximum Propagation Delay Time

700 ns

Maximum Forward Diode Voltage

1.8 V

Minimum Forward Diode Voltage

1.2 V

Maximum Reverse Diode Voltage

5 V

Maximum Forward Diode Current

12 mA

Maximum Power Dissipation

250 mW

Maximum Operating Temperature

+ 100 C

Minimum Operating Temperature

- 40 C

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

H&T Electronics

Part Number:

ACPL-W314-500E

Quantity:

15 000

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Applications Information

Eliminating Negative IGBT Gate Drive

To keep the IGBT firmly off, the ACPL-P314/W314 has a

very low maximum V

to the IGBT gate and emitter (possibly by mounting the

ACPL-P314/W314 on a small PC board directly above the

IGBT) can eliminate the need for negative IGBT gate drive

in many applications as shown in Figure 19. Care should

be taken with such a PC board design to avoid routing

the IGBT collector or emitter traces close to the ACPL-

P314/W314 input as this can result in unwanted coupling

of transient signals into the input of ACPL-P314/W314

and degrade performance. (If the IGBT drain must be

routed near the ACPL-P314/W314 input, then the LED

should be reverse biased when in the off state, to prevent

the transient signals coupled from the IGBT drain from

turning on the ACPL-P314/W314.

Selecting the Gate Resistor (Rg)

Step 1: Calculate R

cation. The IGBT and R

a simple RC circuit with a voltage supplied by the ACPL-

P314/W314.

The V

the peak current of 0.6A. (See Figure 6).

Figure 19. Recommended LED Drive and Application Circuit for ACPL-P314/W314

CONTROL

and the lead inductance from the ACPL-P314/W314

INPUT

COLLECTOR

+5 V

value of 5 V in the previous equation is the V

74XXX

OPEN

24 5

OLPEAK

0.6

270

minimum from the I

specification of 1.0 V. Minimizing

in Figure 19 can be analyzed as

ACPL-P314/W314

peak specifi-

0.1 F

Step 2: Check the ACPL-P314/W314 power dissipation

and increase R

power dissipation (P

power (P

where K

and K

circuit in Figure 19 with I

:, Max Duty Cycle = 80%, Q

The value of 3 mA for I

max. I

Since P

alright for the power dissipation.

Figure 20. Energy Dissipated in the ACPL-P314/W314 and for Each IGBT

Switching Cycle.

AMAX

4.0

3.5

3.0

2.5

2.0

1.5

1.0

0.5

= 10 mA 1.8V 0.8 = 14 mW

= P

= I

= (3 mA + (0.001 mA/nC kHz) 20 kHz 100 nC) 24V +

= P

= (I

ICC

= 85°C:

0.4 J 20 kHz = 128 mW £ 250 mW ( P

= 24V

O(BIAS)

ICC

CCBIAS

over entire operating temperature range.

for this case is less than P

) and the output power (P

is a constant of 0.001 mA/(nC*kHz). For the

Rg – GATE RESISTANCE –

· Q

DutyCycle

O(SWITCHING)

ICC

· f is the increase in I

if necessary. The ACPL-P314/W314 total

) is equal to the sum of the emitter

)

in the previous equation is the

(worst case) = 10 mA, R

Qg = 50 nC

Qg = 100 nC

Qg = 200 nC

Qg = 400 nC

= 100 nC, f = 20 kHz and

O(MAX)

3-PHASE

O(MAX)

+ HVD

- HVDC

100

Q ;

due to switching

@85 C)

Q ;

, R

) f

= 32 : is

= 32

ACPL-W314-500E Avago Technologies US Inc., ACPL-W314-500E Datasheet - Page 11

ACPL-W314-500E

Specifications of ACPL-W314-500E

Available stocks

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