GE D90 Plus Instruction Manual page 268

GROUPED PROTECTION ELEMENTS
Negative-sequence directional overcurrent
258
There are two negative-sequence directional overcurrent protection elements available.
The element provides both forward and reverse fault direction indications through its
output operands
NEG SEQ DIR OC1 FWD
operand is asserted if the magnitude of the operating current is above a pickup level
(overcurrent unit) and the fault direction is seen as forward or reverse, respectively
(directional unit).
The overcurrent unit of the element essentially responds to the magnitude of a
fundamental frequency phasor of either the negative-sequence or neutral current as per
user selection. The zero-sequence current should not be mistaken with the neutral current,
as there is a factor of 3 difference.
A positive-sequence restraint is applied for better performance: a small user-
programmable portion of the positive-sequence current magnitude is subtracted from the
negative or zero-sequence current magnitude, respectively, when forming the element
operating quantity.
The positive-sequence restraint allows for more sensitive settings by counterbalancing
spurious negative and zero-sequence currents resulting from:
• System unbalances under heavy load conditions.
• Transformation errors of current transformers (CTs).
• Fault inception and switch-off transients.
The positive-sequence restraint must be considered when testing for pickup accuracy and
response time (multiple of pickup). The positive-sequence restraint is removed for low
currents. If the positive-sequence current is less than 0.8 pu, the restraint is removed by
setting the constant K to zero. This facilitates response to high-resistance faults when the
unbalance is very small and there is no danger of excessive CT errors, as the current is low.
The operating quantity depends on the way the test currents are injected into the D90
For single-phase injection, I
for I_0 mode if I_1 > 0.8 pu.
The directional unit uses the negative-sequence current (I_2) and negative-sequence
voltage (V_2).
The following tables define the negative-sequence directional overcurrent element.
Table 16: Negative-sequence directional overcurrent unit
Mode
Negative-sequence
Zero-sequence
Table 17: Negative-sequence directional unit
Mode Direction
Negative-sequence Forward
Reverse
Zero-sequence Forward
Reverse
The negative-sequence voltage must be greater than 0.02 pu to be validated for use as a
polarizing signal. If the polarizing signal is not validated neither forward nor reverse
indication is given. In addition, the negative-sequence current (or zero-sequence current)
and
NEG SEQ DIR OC1
= ⅓ × (1 – K) × I for I_2 mode and I
op injected
Operating current
I = |I_2| – K × |I_1|
op
I = 3 × (|I_0| – K × |I_1|) if |I_1| > 0.8 pu
op
I = 3 × |I_0| if |I_1| ≤ 0.8 pu
op
Compared phasors
–V_2 + Z_offset × I_2 and I_2 × 1∠ECA
–V_2 + Z_offset × I_2 and –(I_2 × 1∠ECA)
–V_2 + Z_offset × I_2 and I_2 × 1∠ECA
–V_2 + Z_offset × I_2 and –(I_2 × 1∠ECA)
PLUS
D90 LINE DISTANCE PROTECTION SYSTEM – INSTRUCTION MANUAL
CHAPTER 7: PROTECTION
REV, respectively. The output
Eq. 35
= (1 – K) × I
op injected
Plus
.