Emerson Surge and Signal Protection Manual De Usuario

Hybrid SAD Module

Interceptor MOV Module

Total Surge Current (Amperes)

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Self-sacrificing: This system significantly degrades or

fails with nominal fluctuations or high-energy events.

This design is extremely inconvenient to the customer,

and more importantly, it leaves an opportunity for

critical load upsets/failures.

Oversized components: Large components allow the

system to deal with nominal line voltage, as a result

clamping levels increase, defeating what it is designed

to do.

Our answer lies in a two-part design 

that actively disconnects the nominally

close components during a sustained

overvoltage and transitions from a

sensitive SAD circuit to a hardier MOV

array when subjected to damaging

transient levels. 

First, a solid state comparator network

actively switches the SAD components out

of the transient control circuit when

exposed to line voltages in excess of their

Maximum Continuous Operating Voltage

(MCOV). While SAD components are

removed from the system, an appropriately

sized transient control network is available

for continued protection. During this

disconnect phase, the nominal levels are

continually monitored until the system

voltage is stable, at which point the SAD

circuit is brought back on line.

Second, a regulated amount of high-

energy surge current is transitioned to 

the secondary MOV suppression modules.

This is accomplished through an

impedance matching network utilizing a

series of controlled copper geometries in

conjunction with custom engineered 

high-voltage/high-energy component

distribution. This ultimately limits the

amount of high-energy surge current

through the SAD module to an acceptable

level and diverting the remaining surge

current through the MOV module.