Z1'.T1. BZ1 . PZ1
+ Z1x'.(None + Z1xSiAnomTac.UNB_Alarm).[ T1. INP_Z1EXT]
+ UNB_CR.T1.[ PZ1.Z1'+PZ2.Z2'+PFwd.Aval’]
[(*) from version A2.10 & A3.1]
(See Figure 3 in section 2.7.2.1- Z’ logic description)
Remarks: 4. In case of COS (carrier out of service), the logic swap back to a basic scheme.
5. In the column Data Type:"Configuration" means MiCOM S1 Setting (the parameter is present in the settings).
With the inputs/outputs described above:
2.5.2 Inputs
Data Type Description
T1 to T4 Internal logic Elapse of Distance Timer 1 to 4 (T1/T2/T3/TZp/T4) Tp Internal logic Elapse of transmission time in blocking scheme Z1' to Z4' (*) Internal logic Detection of fault in zones 1 to 4
(lock out by PSWing or Rev Guard) – See figure 3 section 2.7.21
Forward’ Internal logic Fwd Fault Detection l (lockout by reversal guard) UNB_CR Internal logic Carrier Received
INP_COS TS Opto Carrier Out of Service
CSZ1 Configuration Carrier send in case of zone 1 decision CSZ2 Configuration Carrier send in case of zone 2 decision
CSZ4 Configuration Carrier send in case of zone 4 decision (Reverse) None Configuration Scheme without carrier
PZ1 Configuration Permissive scheme Z1 PZ2 Configuration Permissive scheme Z2
PFwd Configuration Permissive Scheme with directional Fwd BZ1 Configuration Blocking scheme Z1
BZ2 Configuration Blocking scheme Z2
INP_Z1EXT Internal logic Zone extension (digital input assigned to an opto by dedicated PSL)
Z1xChannel Fail Configuration Z1x logic enabled if channel fail detected (Carrier out of service = COS)
UNBAlarm Internal logic Carrier Out Of Service
(*) the use of an apostrophe in the above logic (Z'1) is explained in section 2.7.2.1 Figure 3
2.5.3 Outputs
Data Type Description
PDist_Dec Internal logic Distance protection Trip 2.6 Type of trip
Single Pole Z1 Single pole Z2 T1 T2 Tzp T3 T4
0 1 1 1 3 3 3
1 0 1 3 3 3 3
0 0 3 3 3 3 3
1 : Trip 1P if selected in MiCOM S1 otherwise trip 3P 3 : Trip 3P
2.6.1 Inputs
Data Type Description
INP_Dist_Timer_Block TS opto Input for blocking the distance function Single Pole T1 Configuration Trip 1pole at T1 – 3P in other cases Single Pole T1 & T2 Configuration Trip 1pole at T1 /T2 – 3P in other cases PDist_Trip Internal Logic Trip by Distance protection
T1 to T4 Internal Logic End of distance timer by Zone Fault A Internal Logic Phase A selection
Fault B Internal Logic Phase B selection Fault C Internal Logic Phase C selection 2.6.2 Outputs
Data Type Description PDist_Trip A Internal Logic Trip Order phase A PDist_Trip B Internal Logic Trip Order phase B PDist_Trip C Internal Logic Trip Order phase C 2.7 Distance zone settings
NOTE: Individual distance protection zones can be enabled or disabled by means of the Zone Status function links. Setting the relevant bit to 1 will enable that zone, setting bits to 0 will disable that distance zones. Note that zone 1 is always enabled, and that zones 2 and 4 will need to be enabled if required for use in channel aided schemes.
Remarks: 1. .Z3 disable means Fwd start becomes Zp
.Z3 & Zp Fwd disable means Fwd start becomes Z2
.Z3 & Zp Fwd & Z2 disable means Fwd start becomes Z1 2. Z4 disable (see remark 1/2/3 in section 2.4)
2.7.1 Settings table
Menu text Default setting Setting range Step size
Min Max
GROUP 1
DISTANCE ELEMENTS LINE SETTING
Line Length 1000 km
(625 miles)
0.3 km (0.2 mile)
1000 km (625 miles)
0.010 km (0.005 mile) Line Impedance 12/In Ω 0.001/In Ω 500/In Ω 0.001/In Ω
Line Angle 70° –90° +90° 0.1°
Zone Setting
Zone Status 00011111 Bit 0: Z1X Enable, Bit 1: Z2 Enable, Bit 2: Zone P Enable, Bit 3: Z3 Enable, Bit 4: Z4 Enable.
KZ1 Res Comp 1 0 7 0.001
KZ1 Angle 0° 0° 360° 0.1°
Z1 10/In Ω 0.001/In Ω 500/In Ω 0.001/In Ω
Z1X 15/In Ω 0.001/In Ω 500/In Ω 0.001/In Ω
R1G 10/In Ω 0 400/In Ω 0.01/In Ω
R1Ph 10/In Ω 0 400/In Ω 0.01/In Ω
tZ1 0 0 10s 0.002s
KZ2 Res Comp 1 0 7 0.001
KZ2 Angle 0° 0° 360° 0.1°
Z2 20/In Ω 0.001/In Ω 500/In Ω 0.001/In Ω
R2G 20/In Ω 0 400/In Ω 0.01/In Ω
R2Ph 20/In Ω 0 400/In Ω 0.01/In Ω
tZ2 0.2s 0 10s 0.01s
KZ3/4 Res Comp 1 0 7 0.01
Menu text Default setting Setting range Step size
Min Max
KZ3/4 Angle 0° 0° 360° 0.1°
Z3 30/In Ω 0.001/In Ω 500/In Ω 0.001/In Ω
R3G - R4G 30/In Ω 0 400/In Ω 0.01/In Ω
R3Ph - R4Ph 30/In Ω 0 400/In Ω 0.01/In Ω
tZ3 0.6s 0 10s 0.01s
Z4 40/In Ω 0.001/In Ω 500/In Ω 0.01/In Ω
tZ4 1s 0 10s 0.01s
Zone P - Direct. Directional Fwd Directional Fwd or Directional Rev
KZp Res Comp 1 0 7 0.001
KZp Angle 0° 0° 360° 0.1°
Zp 25/In Ω 0.001/In Ω 500/In Ω 0.001/In Ω
RpG 25/In Ω 0 400/In Ω 0.01/In Ω
RpPh 25/In Ω 0 400/In Ω 0.01/In Ω
tZp 0.4s 0 10s 0.01s
Serial Cmp.line (*) Disable Enable Disable Overlap Z Mode (*) Disable Enable Disable Fault Locator
KZm Mutual Comp 0 0 7 0.001
KZm Angle 0° 0° 360° 0.1°
(*) Serial Cmp. Line Enabled (*) Overlap Z Mode Enabled (*) These parameters are available from version A4.0 onwards
• Serial Compensated Line : If enabled, the Directional used in the Deltas Algorithms is set at 90°
(Fwd = Quad1&4 / Rev = Quad 2&3)
P0472ENa
X
R FWD REV
FWD REV
• If disable, the Directional of the Deltas algorithms is set at -30° like conventional algorithms
P0473ENa
X
R FWD
REV FWD
-30˚
FWD
REV
• Overlap Z Mode: If enable, for a fault in Zp (fwd), then Z1 & Z2 will be displayed in LCD/Events/Drec – The internal logic is not modified
2.7.2 Zone Logic Applied
Normally the zone logic used by the distance algorithm is as below:
Z1'
P0462XXa
Z2' Z4'
(with overlap logic the Z2 will cover also the Z1) 2.7.2.1 Zone Logic
The relay internal logic will modify the zones & directionality under the following conditions:
• Power swing detection
• Settings about blocking logic during Power swing
• Reversal Guard Timer
• Type of Logical transmission scheme For Power swing, two signals are considered:
• Presence of Power swing
• Unblocking during power swing
During Power swing the zones are blocked; but can be unblocked with:
• Start of unblocking logic
• Unblocking logic enable in MiCOM S1 on the concerned zone or all zones
During the Reversal guard logic (in case of parallel lines), the reverse directional decision is latched (until that timer is issued) from the switch from Reverse to Forward (for distance scheme with Z1>ZL).
P0474ENa
FIGURE 3 - ZONES UNBLOCKING/BLOCKING LOGIC WITH POWER SWING OR REVERSAL GUARD
2.7.2.2 Inputs
Data Type Description
Z1 Internal Logic Fault detected in zone 1
Z1x Internal Logic Fault detected in zone 1 extended Z2 Internal Logic Fault detected in zone 2
Z3 Internal Logic Fault detected in zone 3 Zp Internal Logic Fault detected in zone p Z4 Internal Logic Fault detected in zone 4 Forward Internal Logic FWD Fault Detected Reverse Internal Logic REV Fault Detected Reversal Guard Internal Logic Reversal guard
Unblock PS Internal Logic Unblocking Power Swing Power Swing Internal Logic Power Swing Detected
INP_Distance_Timer_block TS opto Zones blocked by external input (*) Unblock Z1 Configuration Unblocking Pswing with Z1
Unblock Z2 Configuration Unblocking Pswing with Z2 Unblock Zp Configuration Unblocking Pswing with Zp Unblock Z3 Configuration Unblocking Pswing with Z3 Unblock Z4 Configuration Unblocking Pswing with Z4 Zp_Fwd Configuration Directional Zp set Forward
Z1<ZL Configuration Internal Configuration which determine that Z1 is lower than the length of the line ZL
Perm Z2 Configuration Type of logical distance scheme
(PUP Z2– POP Z2) (**)
Perm Fwd Configuration Type of logical distance scheme (PUP Fwd)
Block Z1 Configuration Type of logical distance scheme (BOP Z1)
Block Z2 Configuration Type of logical distance scheme (BOP Z2)
Remarks: *. Usefull for dedicated logic designed in PSL Facility in Commissioning Test
**. For Aided Distace Scheme – See description in the TRIP LOGIC Table (section 2.8.2.4)
2.7.2.3 Outputs
Data Type Description
Z1x’ Internal Logic Fault detected in zone 1 extended Z1’ Internal Logic Fault detected in zone 1
Z2’ Internal Logic Fault detected in zone 2 Z3’ Internal Logic Fault detected in zone 3 Zp’ Internal Logic Fault detected in zone p Z4’ Internal Logic Fault detected in zone 4
Forward’ Internal Logic Fault Detected in Forward Direction Reverse’ Internal Logic Fault Detected in Reverse Direction
For guidance on Line Length, Line Impedance, kZm Mutual Compensation and kZm mutual compensation Angle settings, refer to section 4.1.
2.7.3 Zone Reaches
All impedance reaches for phase fault protection are calculated in polar form: Z ∠θ, where Z is the reach in ohms, and θ is the line angle setting in degrees, common to all zones.
The line parameters can be adjusted in polar or rectangular mode to give the total positive impedance of the protected line:
Remark: Z limit in MiCOM S1 are adjusted for Ω/phase
• The zone 1 elements of a distance relay should be set to cover as much of the protected line as possible, allowing instantaneous tripping for as many faults as possible. In most applications the zone 1 reach (Z1) should not be able to respond to faults beyond the protected line. For an underreaching application the zone 1 reach must therefore be set to account for any possible overreaching errors. These errors come from the relay, the VTs and CTs and inaccurate line impedance data. It is therefore recommended that the reach of the zone 1 distance elements is restricted to 80 - 85% of the protected line impedance (positive phase sequence line impedance), with zone 2 elements set to cover the final 20% of the line. (Note: Two of the channel aided distance schemes described later, schemes POP Z1 and BOP Z1 use overreaching zone 1 elements, and the previous setting recommendation does not apply).
• The zone 2 elements should be set to cover the 20% of the line not covered by zone 1. Allowing for underreaching errors, the zone 2 reach (Z2) should be set in excess of 120% of the protected line impedance for all fault conditions. Where aided tripping schemes are used, fast operation of the zone 2 elements is required. It is therefore beneficial to set zone 2 to reach as far as possible, such that faults on the protected line are well within reach. A constraining requirement is that, where possible, zone 2 does not reach beyond the zone 1 reach of adjacent line protection. Where this is not possible, it is necessary to time grade zone 2 elements of relays on adjacent lines.
For this reason the zone 2 reach should be set to cover ≤50% of the shortest adjacent line impedance, if possible. When setting zone 2 earth fault elements on parallel circuits, the effects of zero sequence mutual coupling will need to be accounted for.
The mutual coupling will result in the Zone 2 ground fault elements underreaching. To ensure adequate coverage an extended reach setting may be required, this is covered in Section 2.7.7.
• The zone 3 elements would usually be used to provide overall back-up protection for adjacent circuits. The zone 3 reach (Z3) is therefore set to approximately 120% of the combined impedance of the protected line plus the longest adjacent line. A higher apparent impedance of the adjacent line may need to be allowed where fault current can be fed from multiple sources or flow via parallel paths.
• Zone P is a reversible directional zone. The setting chosen for zone P, if used at all, will depend upon its application. Typical applications include its use as an additional time delayed zone or as a reverse back-up protection zone for busbars and transformers. Use of zone P as an additional forward zone of protection may be required by some users to line up with any existing practice of using more than three forward zones of distance protection. Zone P may also be useful for dealing with some mutual coupling effects when protecting a double circuit line, which will be discussed in section 2.7.7.
• The zone 4 elements would typically provide back-up protection for the local busbar, where the offset reach is set to 25% of the zone 1 reach of the relay for short lines (<30km) or 10% of the zone 1 reach for long lines. Setting zone 4 in this way would also satisfy the requirements for Switch on to Fault, and Trip on Reclose protection, as described in later sections. Where zone 4 is used to provide reverse directional decisions for Blocking or Permissive Overreach schemes, zone 4 must reach further behind the relay than zone 2 for the remote relay. This can be achieved by setting:
Z4 ≥ ((Remote zone 2 reach) x 120%) minus the protected line impedance.
2.7.4 Zone Time Delay Settings
(initiated with CVMR (General start convergency))
• The zone 1 time delay (tZ1) is generally set to zero, giving instantaneous operation.
However, a time delay might be employed in cases where a large transient DC component is expected in the fault current, and older circuit breakers may be unable to break the current until zero crossings appear.
• The zone 2 time delay (tZ2) is set to co-ordinate with zone 1 fault clearance time for adjacent lines. The total fault clearance time will consist of the downstream zone 1 operating time plus the associated breaker operating time. Allowance must also be made for the zone 2 elements to reset following clearance of an adjacent line fault and also for a safety margin. A typical minimum zone 2 time delay is of the order of 200ms. This time may have to be adjusted where the relay is required to grade with other zone 2 protection or slower forms of back-up protection for adjacent circuits.
• The zone 3 time delay (tZ3) is typically set with the same considerations made for the zone 2 time delay, except that the delay needs to co-ordinate with the downstream zone 2 fault clearance. A typical minimum zone 3 operating time would be in the region of 400ms. Again, this may need to be modified to co-ordinate with slower forms of back-up protection for adjacent circuits.
• The zone 4 time delay (tZ4) needs to co-ordinate with any protection for adjacent lines in the relay’s reverse direction. If zone 4 is required merely for use in a Blocking scheme, tZ4 may be set high.
Remark: In MiCOM S1, timers settable are: tZi but in the DDB corresponding cells are: Ti
2.7.5 Residual Compensation for Earth Fault Elements
For earth faults, residual current (derived as the vector sum of phase current inputs (Ia + Ib + Ic) is assumed to flow in the residual path of the earth loop circuit. Thus, the earth loop reach of any zone must generally be extended by a multiplication factor of (1 + kZ0) compared to the positive sequence reach for the corresponding phase fault element. kZ0 is designated as the residual compensation factor, and is calculated as:
kZ0 Res. Comp, kZ0 = (Z0 – Z1) / 3.Z1 Ie: As a ratio.
kZ0 Angle, ∠kZ0 = ∠ (Z0 – Z1) / 3.Z1 Set in degrees.
Where:
Z1 = Positive sequence impedance for the line or cable;
Z0 = Zero sequence impedance for the line or cable.
kZ0 CALCULATION DESCRIPTION
If we consider a phase to ground fault AN with analog values VA and IA.
Using symetrical components, VA is described as above:
(1) VA = V1 + V2 + V0 = Z1I1 + Z2I2 + Z0I0
(5) VA = Z1 [IA + kZ0 IR]
(6) Z1 = VA/(IA + kZ0 IR) Particular case
Resistive fault
(7) VA = Z1 [IA + kZ0 IR] + Rdef. Idef (Rdef = Rloop) To determine the distance, Z1 term is extracted.
(8) Z1 = (VA – Rdef. Idef)/(IA + kZ0 IR) with
Rdef: fault resistance (loop)
Idef: current crossing the fault resistance Open line:
Ifault = IR = IA
(9) VA = Z1 IA (1 + kZ0) + Rfault IA (10) Z1 = (VA/IA – Rfault)/(1 + kZ0) The impedance detected will be:
Z = Z1 (1 + kZ0) + Rfault
That is the form used for the result of Z measured with injector providing U, I, ϕ
Separate compensation for each zone (KZ1, KZ2, KZ3/4 and KZp) allows more accurate earth fault reach control for elements which are set to overreach the protected line, such that they cover other circuits which may have different zero sequence to positive sequence impedance ratios (Example: underground cable & overhead line in the protected line).
2.7.6 Resistive Reach Calculation - Phase Fault Elements In MiCOM S1 all resistances are set per loop
The P441, P442 and P444 relays have quadrilateral distance elements, thus the resistive reach (RPh) is set independently of the impedance reach along the protected line/cable.
RPh defines the maximum amount of fault resistance additional to the line impedance for which a distance zone will trip, regardless of the location of the fault within the zone. Thus, the right hand and left hand resistive reach constraints of each zone are displaced by +RPh and -RPh either side of the characteristic impedance of the line, respectively. RPh is generally set on a per zone basis, using R1Ph, R2Ph and RpPh. Note that zones 3 and 4 share the resistive reach R3Ph-R4Ph.
When the relay is set in primary impedance terms, RPh must be set to cover the maximum expected phase-to-phase fault resistance. In general, RPh must be set greater than the maximum fault arc resistance for a phase-phase fault, calculated as follows:
Ra = (28710 x L) / If1.4 RPh ≥ Ra
Where:
If = Minimum expected phase-phase fault current (A);
L = Maximum phase conductor separation (m);
Ra = Arc resistance, calculated from the van Warrington formula (Ω).
Typical figures for Ra are given in Table 1 below, for different values of minimum expected
TABLE 1 - TYPICAL ARC RESISTANCES CALCULATED USING THE VAN WARRINGTON FORMULA The maximum phase fault resistive reach must be limited to avoid load encroachment trips.
Thus, R3Ph and other phase fault resistive reach settings must be set to avoid the heaviest allowable loading on the feeder. An example is shown in Figure 3 below, where the worst case loading has been determined as point “Z”, calculated from:
Impedance magnitude, Z = kV2 / MVA Leading phase angle, ∠Z = cos–1 (PF) Where:
kV = Rated line voltage (kV);
MVA = Maximum loading, taking the short term overloading during out ages of parallel circuits (MVA);
FIGURE 4 - RESISTIVE REACHES FOR LOAD AVOIDANCE
As shown in the Figure, R3Ph-R4Ph is set such as to avoid point Z by a suitable margin.
Zone 3 must never reach more than 80% of the distance from the line characteristic impedance (shown dotted), towards Z. However, where power swing blocking is used, a larger impedance (including ∆R) characteristic surrounds zones 3 and 4, and it is essential also that load does not encroach upon this characteristic. For this reason, R3Ph would be set ≤ 60% of the distance from the line characteristic impedance towards Z. A setting between the calculated minimum and maximum should be applied.
R/Z ratio: For best zone reach accuracy, the resistive reach of each zone would not normally be set greater than 10 times the corresponding zone reach. This avoids relay overreach or underreach where the protected line is exporting or importing power at the instant of fault inception. The resistive reach of any other zone cannot be set greater than R3Ph, and where zone 4 is used to provide reverse directional decisions for Blocking or Permissive Overreach schemes, the zone 2 elements used in the scheme must satisfy R2Ph ≤ (R3Ph-R4Ph) x 80%.