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A.3 ALGORITHMS
APPENDIX A
Obviously, the derived equation describes the temperature evolution for both, a heating process and a cooling process.
The final temperature value θ
, for a permanent current I
, will be (according to [2]):
A
∞
∞
In equation [2], solving for time, you get:
Introducing the following variable change:
that implies to refer temperatures to the steady state value, equations [2] and [4] can be written as:
where I' represents the current value in per unit, based on the permanent current, this is:
To compute the tripping time, substitute in [7], with θ' = 1, and you get:
It is necessary that I > 1.
Equation [9], can also be written as a function of current, in p.u., if it has been maintained permanently (in other case, it is
necessary to compute the equivalent current), that is represented by the letter "v":
Equation [10], represents the basic tripping algorithm for a thermal image relay, that for a given τ and I
, can be drawn, in
∞
general using a logarithm plane, using "v" as the parameter, as shown in Figure A–1: and Figure A–2:
A-4
MIFII Digital Feeder Relay
GEK-106237P
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