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Optimation, Inc.

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OptiLogic Series

Digital Outputs

Digital outputs are used to turn “loads”

on and off. “Loads” may be lights, motors,

solenoids, or any type of on/off device found in

the “real world”.

Digital outputs in the OptiLogic series

come in three types - relay, transistor and solid

state relay. Each type has applications it is best

suited for. The following is a general list of

application characteristics for each output type.

Relay

•

Low contact loss

•

AC or DC

•

Moderate to high current rating

•

Low cost

Should not be used for

•

Ultra low current switching (less than 10mA)

•

Switching loads at high frequency

Transistor

•

DC application only

•

Low current rating

•

High frequency switching

•

Low cost

Solid State Relay

•

AC application

•

Any switching frequency

•

Moderate current

•

Moderate cost

Relay Outputs

Relays are basically electrically

controlled mechanical switches. All current

OptiLogic Relay output boards utilize form A

relays - i.e. the contact is either open or closed.

Relay Loads

Relays are affected by the type of load

that is switched. Inductive loads (solenoids,

motors, etc.) tend to wear the relay much more

than resistive loads (lights, heaters, etc.).

Inductive load wear is due to the fact that

inductive loads will continue to conduct current

for a period, even after the circuit is broken. This

current flow builds up opposing polarity charges

between the contact segments that just

separated. This makes the two segments attract

each other - making opening the contact more

difficult. It also can result in arcing while the

contact is being opened. Arcing, in turn, builds

up carbon deposits, i.e. wear.

This situation can be improved for DC

inductive circuit loads by the addition of

external diode protection of the circuit. The

figure below illustrates diode protection. When

the contact is closed, the diode is reverse biased

and no current flows through it. When the

contact opens, current will continue to flow

through the inductive load. The diode provides a

path for current flow. The result that is the

energy is dissipated in the inductive coil and not

the relay contact.

Note : Do not use this circuit for AC loads.

Output module

isolation

From

OptiLogic

processor

Inductive load

Diode protection