3
2
1
2
⋅
+
⋅
+ ⋅
U
U
U
U
L
L2
L3
=
a
a
EQUATION707 V2 EN
(Equation 26)
Where:
U
L1
, U
L2
and U
L3
IEC00000275 V1 EN
are the measured phase voltages
2
3
3
1
0, 5
2
j
a
e
j
p
×
= ×
= -
+
.
IECEQUATION00022 V2 EN
4.
Compare the result with the set value of the negative-sequence operating voltage
(consider that the set value
3U2>
is in percentage of the base voltage
UBase
).
5.
. Then slowly increase the measured current in one phase
until the BLKU signal disappears.
6.
Record the measured current and calculate the corresponding negative-sequence
current according to the equation (observe that the currents in the equation are
phasors):
2
1
2
3
2
3
L
L
L
I
I
a I
a I
×
=
+
×
+ ×
IECEQUATION00021 V1 EN
(Equation 29)
Where:
1
2
3
L
L
L
I
I and I
,
IECEQUATION00020 V1 EN
are the measured phase currents
2
3
3
1
0, 5
2
j
a
e
j
p
×
= ×
= -
+
.
IECEQUATION00022 V2 EN
7.
Compare the result with the set value of the negative-sequence operating
current. Consider that the set value
3I2<
is in percentage of the base current
IBase
.
10.8.2.3
Measuring the operate value for the zero-sequence function
Measure the operate value for the zero-sequence function, if included in the IED.
1.
Simulate normal operating conditions with the three-phase currents in phase
with their corresponding phase voltages and with all of them equal to their rated
values.
2.
Slowly decrease the measured voltage in one phase until the BLKU signal
appears.
3.
Record the measured voltage and calculate the corresponding zero-sequence
voltage according to the equation (observe that the voltages in the equation are
phasors):
1MRK 511 360-UEN A
Section 10
Testing functionality by secondary injection
Bay control REC670 2.1 IEC
137
Commissioning manual