Restricted earth-fault protection function block description
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1 function block description Document ID: PRELIMINARY VERSION
2 User s manual version information Version Date Modification Compiled by Preliminary Preliminary version, without technical information Petri PRELIMINARY VERSION 2/16
3 CONTENTS 1 Restricted earth-fault protection function Structure of the restricted earth-fault protection algorithm The Fourier calculation (Fourier) The zero-sequence current calculation (Zero-sequence current calculation ) Directional decision (Directional decision) The zero-sequence differential characteristics (Differential characteristics) The decision logic (Decision logic) Technical summary Technical data The measured values The parameters The binary input status signals Binary output status signals The function block Example for the setting calculation of the zero-sequence differential protection function PRELIMINARY VERSION 3/16
4 1 Restricted earth-fault protection function The restricted earth-fault protection function is basically a low-impedance differential protection function based on zero sequence current components. It can be applied to transformers with grounded neutral. The function compares the measured neutral current and the calculated zero sequence current component of the phase currents and generates a trip command if the difference of these currents is above the characteristics. 1.1 Structure of the restricted earth-fault protection algorithm Fig.1-1 shows the structure of the restricted earth-fault protection (DIF87N) algorithm. IprimL1 IprimL2 IprimL3 IN Parameters Preparation Fourier IL1 Fourier IL2 Fourier IL3 Fourier IN Zero - sequence current calculation Directional decision Differential characteristics magnitude DIF87N Decision logic Binary outputs Measured values Status signals Figure 1-1 Structure of the restricted earth-fault protection algorithm The inputs for the preparation are: the sampled values of three primary phase currents, the sampled value of the neutral current. The outputs of the preparation are: the RMS values of the fundamental Fourier components of the phase currents and that of the neutral current. The inputs for the DIF87N function are: the RMS values of the fundamental Fourier components of the phase currents and that of the neutral current, parameters, status signal. The outputs of the DIF87N function are: the binary output status signal, the measured values for displaying. PRELIMINARY VERSION 4/16
5 The software modules of the differential protection function: Fourier calculations These modules calculate the basic Fourier current components of the phase currents and that of the neutral current individually. These modules belong to the preparatory phase. Zero sequence current calculation This module calculates the zero sequence current components based on the Fourier components of the phase currents. These modules belong to the preparatory phase. Directional decision This module compares the direction of the neutral current and that of the calculated zero sequence current. In case of small zero sequence components of the high fault currents in the phases, this decision improves the stability of the function. Differential characteristics This module performs the necessary calculations for the evaluation of the percentage differential characteristics and decides if the differential current is above the characteristic curve of the differential protection function. This curve is the function of the restraint current, which is the maximum of the phase currents and the current of the neutral point. The result of this calculation is needed for the decision logic. Decision logic The decision logic module combines the status signals, binary and enumerated parameters to generate the trip command of the function. The following description explains the details of the individual components. PRELIMINARY VERSION 5/16
6 1.2 The Fourier calculation (Fourier) These modules calculate the basic Fourier current components of the phase currents and that of the neutral current individually. The magnitudes of these currents are matched to each other using the current transformer rated current values. These modules belong to the preparatory phase. IprimL1 IprimL2 IprimL3 IN Fourier IL1Four IL2Four IL3Four INFour Figure 1-2 Principal scheme of the Fourier calculation The inputs are the sampled values of: the three phase currents of the primary side (IprimL1, IprimL2, IprimL3) the current measured at the neutral point (IN) The outputs are the basic Fourer components of the analyzed currents (IL1Four, IL2Four, IL3Four, INFour). The integer parameters of the Fourier calculation are listed in Table 1-1. Parameter name Title Unit Min Max Step Default Parameters for the current magnitude compensation: DIF87N_TRPri_IPar_ TR Primary comp. % DIF87N_TRNeut_IPar_ TR neutral % Table 1-1 The integer parameters of the Fourier calculation PRELIMINARY VERSION 6/16
7 1.3 The zero sequence current calculation (Zero sequence current calculation ) This module calculates the zero sequence current component based on the Fourier components of the phase currents. This module belongs to the preparatory phase. The inputs are the basic Fourier components of the phase currents (IL1Four, IL2Four, IL3Four). The outputs are the Fourier components of the calculated zero sequence current (3IoFour). IL1Four IL2Four IL3Four 3IoFour=IL1Four+ IL2Four+ IL3Four 3IoFour Figure 1-3 Principal scheme of the zero sequence current calculation 1.4 Directional decision (Directional decision) This module compares the direction of the neutral current and that of the calculated zero sequence current. In case of small zero sequence component of the high fault currents in the phases, this decision improves the stability of the function. For the directional decision, the positive directions are drawn in Figure 1-4. In this system, if the angle between the calculated zero sequence current 3Io and the measured neutral current IN is out of the range of ±90 degrees, then the restricted earth fault protection can be blocked, the status signal DIF87N_StDir_GrI_ (Dir.element Start) is set to TRUE value. The blocking is decided in the decision logic of the function, using the binary parameter DIF87N_DirCheck_BPar_. PRELIMINARY VERSION 7/16
8 IL1 IL2 IL3 IN Figure 1-4 Positive directions for the directional decision The inputs are the Fourier components of the calculated zero sequence current (3IoFour) and that of the neutral current (INFour). The binary output status signal of the directional decision is shown in Table 1-2. Binary output signals Signal title Explanation DIF87N_StDir_GrI_ Dir.element Start Directional blocking signal of the zerosequence directional element Table 1-2 The binary output status signals of the directional decision 3IoFour INFour BLOCK DIF87N_StDir_GrI_ INFour 3IoFour Figure 1-5 Principal scheme of the directional decision 1.5 The zero sequence differential characteristics (Differential characteristics) This module performs the necessary calculations for the evaluation of the percentage differential characteristics, and decides if the differential current is above the characteristic curve of the zero sequence differential protection function. This curve is the function of the restraint current, which is the maximum of the phase currents and the current of the neutral point. The result of this calculation is processed in the decision logic. PRELIMINARY VERSION 8/16
9 The differential current is calculated using the following formula: Diff Current IL1Four IL2Four IL3Four INFour The restraint current is calculated using the following formula: Bias Current MAX(IL1Fou r, IL2Four, IL3Four, INFour) Based on these values, the zero sequence differential protection characteristics are shown in Figure 1-6. Diff Current Slope= DIF87N_f2_IPar DIF87N_f1_IPar_ Bias Current DIF87N_f2Brk_IPar_ Figure 1-6 The zero sequence differential protection characteristics IL1Four IL2Four Diff Current DIF87N_GenTr_GrI_i _ IL3Four INFour Slope= DIF87N_f2_IPar Measured values DIF87N_f1_IPar_ DIF87N_f2Brk_IPar_ Bias Current Figure 1-7 Principal scheme of the zero sequence differential protection PRELIMINARY VERSION 9/16
10 The measured values of the restricted earth-fault protection function are listed in Table 1-3. Measured value Title Dim. Explanation DIF87N_Id_OLM_ Diff Current In % The calculated differential current DIF87N_Bias_OLM_ Bias Current In % The calculated restraint current Table 1-3 The measured analogue values of the zero sequence differential protection characteristics The binary output status signal of the differential protection characteristics is shown in Table 1-4. Binary output signals Signal title Explanation DIF87N_GenTr_GrI_i General Trip_i Internal general trip signal of the differential characteristics Table 1-4 The binary output status signals of the zero sequence differential protection characteristics The parameters of the differential protection characteristics are explained in the following tables. The integer parameters of the differential protection characteristics are listed in Table 1-5. Parameter name Title Unit Min Max Step Default Base sensitivity: DIF87N_f1_IPar_ Base sensitivity % Slope of the second section of the characteristics: DIF87N_f2_IPar_ Second part Break point of the characteristic line: DIF87N_f2Brk_IPar_ Break point Table 1-5 The integer parameters of the zero sequence differential protection characteristics The binary input signal serves to increase the base sensitivity by 4 times. The conditions of increasing are defined by the user, applying the graphic equation editor. Binary input signal DIF87N_UnSens_GrO_ Explanation Output status of a graphic equation defined by the user to increase the base sensitivity by 4 times Table 1-6 The binary input signal of the zero sequence differential protection characteristics PRELIMINARY VERSION 10/16
11 1.6 The decision logic (Decision logic) The decision logic module combines the status signals, binary and enumerated parameters to generate the trip command of the function. DIF87N_StDir_GrI_ DIF87N_DirCheck_BPar_ DIF87N_Blk_GrO_ DIF87N_GenTr_GrI_i AND OR NOT AND DIF87N_GenTr_GrI _ DIF87N_Oper_EPar Figure 1-8 The logic scheme of the restricted earth-fault protection function Binary input signals Signal title Explanation DIF87N_GenTr_GrI_i DIF87N_StDir_GrI_ General Trip_i Dir.element Start Internal general trip signal of the differential characteristics Directional blocking signal restricted earth-fault protection function Table 1-7 The binary input status signals of the zero sequence differential protection characteristics The restricted earth-fault protection function has a binary input signal, which serves the purpose of disabling the function. The conditions of disabling are defined by the user applying the graphic equation editor. Binary input signal DIF87N_Blk_GrO Explanation Output status of a graphic equation defined by the user to disable the differential protection function. Table 1-8 The binary input signal of the restricted earth-fault protection function The binary output signals of the restricted earth-fault protection function are listed in Table 1-9. Binary output signals Signal title Explanation DIF87N_GenTr_GrI_ DIF87N_StDir_GrI_ General Trip Dir.element Start General trip signal of the zero sequence differential protection characteristics Directional blocking signal of the restricted earth-fault protection function Table 1-9 The binary output status signals of the zero sequence differential protection characteristics PRELIMINARY VERSION 11/16
12 The enumerated parameter of the restricted earth-fault protection function is shown in Table 1-10: Parameter name Title Selection range Default Parameter to enable the zero sequence differential protection function: DIF87N_Oper_EPar_ Operation Off,On On Table 1-10 The enumerated parameters of the restricted earth-fault protection function The Boolean parameter of the restricted earth-fault protection function is shown in Table 1-14: Parameter name Title Default Explanation DIF87N_DirCheck_BPar_ Directional check True Enabling the directional checking of the measured and calculated zero sequence currents Table 1-11 The Boolean parameters of the restricted earth-fault protection function The restricted earth-fault protection function generates a trip signal if the differential current as the function of the bias current is above the differential characteristic lines and the function is not blocked and the operation of the function is enabled by parameter setting. Blocking can be caused by the directional decision if it is enabled by parameter setting and the angle of the currents is in the blocking area or the user has composed a blocking graphic equation, and the conditions result a TRUE value for the blocking. PRELIMINARY VERSION 12/16
13 1.7 Technical summary Technical data Function Effective range* Accuracy* Operating characteristic Reset ratio Unrestrained differential setting Base sensitivity Operate time Reset time *To be defined by types tests The measured values The measured values of the restricted earth-fault protection function are listed in Table Measured value Title Dim. Explanation DIF87N_Id_OLM_ Diff Current In % The calculated differential current DIF87N_Bias_OLM_ Bias Current In % The calculated restraint current Table 1-12 The measured analogue values of the restricted earth-fault protection function The parameters of the restricted earth-fault protection function are explained in the following tables. PRELIMINARY VERSION 13/16
14 1.7.3 The parameters The enumerated parameter of the restricted earth-fault protection function is shown in Table 1-13: Parameter name Title Selection range Default Parameter to enable the zero sequence differential protection function: DIF87N_Oper_EPar_ Operation Off,On On Table 1-13 The enumerated parameters of the restricted earth-fault protection function The Boolean parameter of the restricted earth-fault protection function is shown in Table 1-14: Parameter name Title Default Explanation DIF87N_DirCheck_BPar_ Directional check True Enabling the directional checking of the measured and calculated zero sequence currents Table 1-14 The Boolean parameters of the restricted earth-fault protection function The integer parameters of the restricted earth-fault protection function are listed in Table Parameter name Title Unit Min Max Step Default Parameters for the current magnitude compensation: DIF87N_TRPri_IPar_ TR Primary comp. % DIF87N_TRNeut_IPar_ TR neutral % Base sensitivity: DIF87N_f1_IPar_ Base sensitivity % Slope of the second section of the characteristics: DIF87N_f2_IPar_ Second part Break point of the characteristic line: DIF87N_f2Brk_IPar_ Break point Table 1-15 The integer parameters of the restricted earth-fault protection function Floating-point parameters The restricted earth-fault protection function has no floating-point parameters. Timer parameters The restricted earth-fault protection function has no timers. PRELIMINARY VERSION 14/16
15 1.7.4 The binary input status signals The restricted earth-fault protection function has a binary input signal, which serves the purpose of disabling the function. The conditions of disabling are defined by the user, applying the graphic equation editor. The other binary input signal serves to increase the base sensitivity by 4 times. The conditions of increasing the base sensitivity are defined by the user, applying the graphic equation editor. Binary input signal DIF87N_Blk_GrO DIF87N_UnSens_GrO_ Explanation Output status of a graphic equation defined by the user to disable the differential protection function. Output status of a graphic equation defined by the user to increase the base sensitivity by 4 times Table 1-16 The binary input signal of the restricted earth-fault protection function Binary output status signals The binary output status signals of the restricted earth-fault protection function are listed in Table Binary output signals Signal title Explanation DIF87N_GenTr_GrI_ General Trip General trip signal of the restricted earth-fault protection function Table 1-17 The binary output status signals of the restricted earth-fault protection function The function block The function block of the restricted earth fault protection function is shown in Figure 1-9. This block shows all binary input and output status signals that are applicable in the graphic equation editor. Figure 1-9 The function block of the restricted earth-fault protection function PRELIMINARY VERSION 15/16
16 1.8 Example for the calculation of settings of the zero sequence differential protection function As an example, the transformer data: Sn = 25 MVA U1/U2 = 120/22 kv/kv Y(d)y6 Current transformers: CT1 600/1 A/A CT2 800/1 A/A CTN 250/1 A/A The selected base current is the primary rated current of the transformer: 120 A. If a lower current value is selected, the zero sequence differential protection becomes more sensitive. REF on the secondary side: I1np = 120 A I2np = 656 A On the secondary side of the CT I2n = 0.82 A INp = 656 A On the secondary side of the CTIN = 2.6 A The setting parameters: Parameter name Title Setting value DIF87N_TRPri_IPar_ TR Primary comp. 82% DIF87N_TRNeut_IPar_ TR neutral 260% The base sensitivity refers to the selected base current expressed in %, the slope is the ratio of the differential current and the bias current expressed in %. PRELIMINARY VERSION 16/16
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