Philosophy

Question 1

Why do protection systems operate in zones?

Answer 1

a) in the event of a fault, only the protection for that zone will trip; b) nothing is left unprotected

Question 2

How is a ‘zone’ defined?

Answer 2

CTs define the boundaries of a zone (i.e. current can be checked on both sides of plant).

Question 3

Why might HV primary system faults vary in their impedence?

Answer 3

Might have a low-impedance, short-circuit fault, or a high-impedance fault (e.g. lightning strike stretching from phase to ground).

Question 4

Define a ‘fault’

Answer 4

a ‘disruptive event resulting in a departure of the power system from the normal operation condition’

Question 5

What is Powerlink’s basic protection philosophy?

Answer 5

To allow for a fault anywhere on the system and for any one thing to go wrong (hence the X and Y protection)

Question 6

What is ‘unit protection’? Give an example.

Answer 6

A scheme that protects a specific area (e.g. transformer). Based off Kirchoffs Current Law. Examples: bus zone and transformer differential protection

Question 7

What is ‘non-unit protection’?

Answer 7

Doesn’t have exact zone boundaries. Based off ‘time grading’ of relays; i.e. closest relay repsonds first.

Question 8

What are some required operating times for 250kV+ protection?

Answer 8

CB fail: ~260ms

faulted end: 100ms

Question 9

Why is ‘stability’ important in a unit protection system?

Answer 9

If a fault occurs on a feeder close to a substation, there will be abnormally high bus currents (all the other feeders will try and feed more current in to this fault). The unit bus must stay ‘steady’ (i.e. stable; not operate) and let the feeder protection do its thing.

In other words, it ensures protection won’t operate outside its zone.