8-36 L60 Line Phase Comparison System GE Multilin8.2 SINGLE-POLE TRIPPING 8 THEORY OF OPERATION88.2.2 PHASE SELECTIONThe L60 uses phase relations between current symmetrical components for phase selection. First, the algorithm validates ifthere is enough zero-sequence, positive-sequence, and negative-sequence currents for reliable analysis. The comparisonis adaptive; that is, the magnitudes of the three symmetrical components used mutually as restraints confirm if a given com-ponent is large enough to be used for phase selection. Once the current magnitudes are validated, the algorithm analyzesphase relations between the negative-sequence and positive-sequence currents and negative-sequence and zero-sequence currents (when applicable) as illustrated below.Figure 8–29: PHASE SELECTION PRINCIPLE (ABC PHASE ROTATION)Due to dual comparisons, the algorithm is very secure. For increased accuracy and to facilitate operation in weak systems,the pre-fault components are removed from the analyzed currents. The algorithm is very fast and ensures proper phaseselection before any of the correctly set protection elements operates.Under unusual circumstances such as weak-infeed conditions with the zero-sequence current dominating during anyground fault, or during cross-country faults, the current-based phase selector may not recognize any of the known fault pat-tern. If this is the case, voltages are used for phase selection. The voltage algorithm is the same as the current-based algo-rithm; for example, phase angles between the zero-sequence, negative-sequence, and positive-sequence voltages areused. The pre-fault values are subtracted prior to any calculations.The pre-fault quantities are captured and the calculations start when the disturbance detector (50DD) operates. When anopen pole is declared, the phase selector resets all its outputs operands and ignores any subsequent operations of the dis-turbance detector.The phase selector runs continuously. When there is no disturbance in the power system, and the disturbance detector(50DD) from the source assigned as the DISTANCE SOURCE is reset, then the PHASE SELECT VOID FlexLogic operand is setand all other phase selector operands are reset. All current and voltage sequence components are memorized and contin-uously updated.When the disturbance detector (50DD) operates, memory stops being updated and retains two cycles of old current andvoltage values. First, purely fault components of current and voltage are calculated by removing the pre-fault (memory)quantities from presently calculated values. A series of conditions are checked with respect to magnitudes and phaseangles of current and voltage symmetrical components in order to detect the fault type. Secondly, currents are used to iden-tify the fault type (AG, BG, CG, AB, BC, CA, ABG, BCG or CAG) according to the Phase selection principle figure above. Ifthe currents fail to identify the fault type, and voltages are available, then voltages are used. If any of the above types isdetermined, then the corresponding FlexLogic operand below is asserted.837725A1.CDRAB,ABGCA,CAGBC,BCGAGAG,BCGI 2F I 2FI 1F I0FBGCG,ABGCG BG,CAG
