NERC Protection Coordination Webinar Series June 16, Phil Tatro Jon Gardell
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1 Power Plant and Transmission System Protection Coordination Phase Distance (21) and Voltage-Controlled or Voltage-Restrained Overcurrent Protection (51V) NERC Protection Coordination Webinar Series June 16, 2010 Phil Tatro Jon Gardell
2 Disclaimer 2 The information from this webcast is provided for informational purposes only. An entity's adherence to the examples contained within this presentation does not constitute compliance with the NERC Compliance Monitoring and Enforcement Program ("CMEP") requirements, NERC Reliability Standards, or any other NERC rules. While the information included in this material may provide some of the methodology that NERC may use to assess compliance with the requirements of certain Reliability Standards, this material should not be treated as a substitute for the Reliability Standard or viewed as additional Reliability Standard requirements. In all cases, the entity should rely on the language contained in the Reliability Standard itself, and not on the language contained in this presentation, to determine compliance with the NERC Reliability Standards.
3 Agenda 3 Technical Reference Document Overview Proposed Modifications Objectives Description of Protection Functions Discuss and Describe System Events that Could Create Conditions that Would Cause Operation of These Functions Detailed Coordination Information Function 21 Phase Distance Protection Function 51V Voltage-Controlled or Voltage-Restrained Overcurrent Protection
4 Agenda 4 What is Important to Coordination Settings that Protect the Generator Back Up for Transmission System Protection Calculation of Apparent Impedance with Infeed Current Generator Field Forcing Effects During System Stressed Voltage Conditions Loadability Issues During Stressed System Conditions Question and Answer
5 Technical Reference Document Overview 5 Introduction and Background Blackout Recommendation TR-22 SPCS s Assignment The Need for this Technical Reference Document - History and Background: August 14, 2003 Blackout Subsequent Events
6 Technical Reference Document Overview 6 Support of PRC Standards Benefits of Coordination: To the Generator Owner To the Transmission Owner To the Planning Coordinator Reliability of the Bulk Electric System and Power Delivery to the Customer
7 Proposed Modifications to the Technical Reference Document 7 SPCS has received feedback on the document that requires revisions to Section 3.1 and Appendix E The level of field forcing represented in the existing document is not as severe as intended The document is being revised based on observed generator loading during system disturbances and computer modeling Two methods are under development for assessing loadability of phase distance protection SPCS will be seeking Planning Committee approval of revisions to the Technical Reference Document
8 Proposed Modifications to the Technical Reference Document 8 The substantive revisions are included in this Webinar session Section 3.1 and Appendix E Phase distance discussion and examples will be modified to provide more comprehensive guidance on generator relay loadability Section 3.10 Voltage-restrained overcurrent examples have been revised Other modifications: Achieve common usage of terms Remove discrepancies between and among Tables 2 and 3 and the excerpts from these tables Correct some figures Correct formatting problems
9 Objective 9 Increase knowledge of recommended generator protection for system back-up using phase distance and voltage-controlled or voltage-restrained overcurrent functions. Facilitate improved coordination between power plant and transmission system protection for these specific protection functions.
10 Scope 10 Focus is on the reliability of the Bulk Electric System. This Technical Reference Document is applicable to all generators, but concentrates on synchronous generators connected at 100-kV and above. Distributed Generation (DG) facilities connected to distribution systems are outside the scope of this document.
11 The Need for Phase Distance System Back-Up Protection Function The distance relay applied for this function is intended to isolate the generator from the power system for a fault which is not cleared by the transmission line breakers. Within its operating zone, the tripping time for this relay must coordinate with the longest time delay for the phase distance relays on the transmission lines connected to the generating substation bus. IEEE C Guide for AC Generator Protection, Section
12 The Need for Voltage-Controlled or -Restrained Overcurrent Protection Function 51V 12 Its function is to provide backup protection for system faults when the power system to which the generator is connected is protected by time-current coordinated protections. The type of overcurrent device generally used for system phase fault backup protection is either a voltagerestrained or voltage-controlled time-overcurrent relay. Both types of relays are designed to restrain operation under emergency overload conditions and still provide adequate sensitivity for the detection of faults. IEEE C Guide for AC Generator Protection, Section
13 Relay One-Line Showing All Generator Protection and Identifying Function 21 and 51V 13 87U 87T 51T 87G R BF 59GN/ 27TH 51TG /27 51V 78
14 System Events that Could Cause Undesired Operation of These Protection Functions 14 System Fault Conditions Miscoordination with system protection during a system fault Non-Fault Stressed System Conditions System Low Voltage Conditions Loadability Concerns Events such as August 14, 2003 Blackout with embedded stressed system conditions Loss of Critical Units
15 General Data Exchange Requirements Generator Owner Data and Information 15 The following general information must be exchanged in addition to relay settings to facilitate coordination, where applicable: Relay scheme descriptions Generator off nominal frequency operating limits CT and VT/CCVT configurations Main transformer connection configuration Main transformer tap position(s) and impedance (positive and zero sequence) and neutral grounding impedances High voltage transmission line impedances (positive and zero sequence) and mutual coupled impedances (zero sequence) Generator impedances (saturated and unsaturated reactances that include direct and quadrature axis, negative and zero sequence impedances and their associated time constants) Documentation showing the function of all protective elements listed above
16 General Data Exchange Requirements Transmission or Distribution Owner Data and Information 16 The following general information must be exchanged in addition to relay settings to facilitate coordination, where applicable: Relay scheme descriptions Regional Reliability Organization s off-nominal frequency plan CT and VT/CCVT configurations Any transformer connection configuration with transformer tap position(s) and impedance (positive and zero sequence) and neutral grounding impedances High voltage transmission line impedances (positive and zero sequence) and mutual coupled impedances (zero sequence) Documentation showing the function of all protective elements Results of fault study or short circuit model Results of stability study Communication-aided schemes
17 Detailed Coordination Information for Functions 21 and 51V 17 Detailed coordination information is presented under seven headings, as appropriate, for each function in the document. The following slides present a section-by-section summary for Functions 21 and 51V.
18 Document Format Seven Sub-Sections for Each Protection Function 18 Purpose Coordination of Generator and Transmission System Faults Loadability Other Conditions, Where Applicable Considerations and Issues Coordination Procedure Test Procedure for Validation Setting Considerations Examples Proper Coordination Improper Coordination Summary of Detailed Data Required for Coordination of the Protection Function Table of Data and Information that Must be Exchanged
19 Purpose Function Machine Only Coverage Provide thermal protection of the generator for a transmission fault that is not cleared System Trip Dependability Provide relay failure backup protection for all elements connected to the GSU high-side bus
20 Coordination of Generator and Transmission System Function Faults The detection of a fault is most easily demonstrated by an example. In the example, it is assumed that a transmission line relay failure has occurred and the fault is at the far end of the protected line. The example presents solutions that can be used to permit tripping for the fault while not tripping for nonfault conditions when the generator is not at risk.
21 Coordination of Generator and Transmission System Function Loadability C presents a range from 150 percent to 200 percent of the generator MVA rating at rated power factor as settings that will not operate for normal generator outputs. This setting can be restated in terms of impedance as per unit on the machine base. This document addresses phase distance relay applications for which the voltage regulator action could cause an incorrect trip based on a fixed-field model basis. To fully address dynamic effects during stressed system conditions, a conservative load point(s) or a dynamic simulation(s) of the unit and excitation system is required to properly assess the security of this protection function. The SPCS is developing two methods to assess and model these dynamic effects. Most exciters have a field forcing function that enables the exciter to go beyond its full load output. These outputs can last up to several seconds before controls reduce the exciter field currents to rated output.
22 Assessing Generator Relay Loadability Method 1 (Under Development) 22 Conservative, but simple Evaluate apparent impedance based on: Active power loading at rated MW Reactive power loading at a Mvar level of 150 percent times rated MW (e.g. 500 MW and 750 Mvar) Generator step-up (GSU) high-side voltage at 0.85 pu Load level selected based on observed unit loading during August 14, 2003 blackout and other subsequent events Load level believed to be a conservatively high level of reactive power for 0.85 per unit high-side voltage
23 Assessing Generator Relay Loadability Method 2 (Under Development) 23 May be applied when the conservative, but simple test in Method 1 restricts the desired relay setting Allows for more extensive evaluation of the worst-case expected operating point based on characteristics of the specific generator Operating point determined from dynamic modeling of the apparent impedance Evaluation is conducted using a dynamic simulation based on: Active power loading at rated MW Reactive power loading at a Mvar level based on simulated response of the unit to depressed transmission system voltage Generator step-up (GSU) high-side voltage at 0.85 pu prior to fieldforcing
24 Coordination of Generator and Transmission System Function Coordination with Breaker Failure The 21 function will detect transmission system faults that normally will be cleared by the transmission system relays. The 21 function time delay must be set to coordinate with the breaker failure clearing times with a reasonable margin. This requirement is necessary for all transmission protection zones (protected elements) within which the 21 relay can detect a fault.
25 Considerations and Issues Function It may be necessary to set the impedance relay to detect faults in another zone of protection to ensure trip dependability, i.e. to provide relay failure protection. When it is not possible to set the 21 function to detect these faults due to the effect of infeed from other fault current sources, other means for providing relay failure protection is necessary. The three-phase fault is the most challenging to detect. Must be secure for loading conditions. Must be secure for transient conditions. The impedance relay must not operate for stable system swings. This function becomes increasingly susceptible to tripping for stable swings as the apparent impedance setting of the relay increases; e.g. when the impedance relay is set to provide remote backup. The best way to evaluate susceptibility to tripping is with a stability study.
26 Coordination Procedure Function Step 1 Generator Owner and Transmission Owner agree on the reach and time delay settings for the system and generator protection 21 functions. Step 2 Generator Owner verifies that the generator 21 relay is coordinated with OEL functions of the excitation system. This is especially important when the excitation system of the machine is replaced. At all times, the generation protection settings must coordinate with the response times of the over-excitation limiter (OEL) and V/Hz limiter on the excitation control system of the generator. Step 3 Generator Owner and Transmission Owner review any setting changes found to be necessary as a result of step two. Depending on the results of step 2, this may be an iterative process, and may require additional changes to the transmission protection system.
27 Example - Proper Coordination Function This example illustrates a relay setting process for the trip dependability application, but includes the considerations applicable for generator thermal backup protection. In this example from the Technical Reference Document, the following data is used: MVA MVA pf pf Xx d " = = pu X x d = d '.21 pu X tr = 10% 10% 975 MVA 625 MVA 345 kv 40 Ω Z sys Bus A 20 Ω 20 kv Relays for this line fail Ω fault Z sys Bus B Z sys Bus C 40 Ω 20 Ω
28 Example - Proper Coordination Function The 21 function is set to provide generator trip dependability for system faults The relay is set to reach 120 percent of the longest line connected to the GSU high-side bus (with infeed). The relay reach in per unit at the fault impedance angle on the generator base necessary to reliably detect the line-end fault with 20 percent margin is per unit. This setting, including a reasonable margin, should not exceed a load impedance that is calculated from the generator terminal voltage and stator current. Secure operation must be confirmed using either method 1 or method 2 for assessing generator relay loadability.
29 Example - Proper Coordination Function Method 1 is used to calculate the operating point to assess relay loadability The generator is at a stressed output level of j1152 MVA = 1385 MVA at The calculated load impedance = 0.62 pu at [1] The desired relay setting is plotted against the operating point to assess relay loadability [1] Calculation details are provided in Appendix E of the Technical Reference Document
30 Example - Proper Coordination Function The plot shows that the desired reach cannot be achieved with a mho characteristic. In this example blinders are utilized to achieve the desired reach for dependability and to coordinate with the loadability requirement for security Desired Relay Setting: pu Reach at Maximum Torque Angle = 85º Load Point Rated Power Factor Angle = 31.8º (0.85 pf) Blinders Applied at ± 0.25 pu at 85º 2.0
31 Function 21 Methods To Increase Loadability 31 A number of methods are available; some are better suited than others to improving loadability for a wide range of operating points. The stressed system operating point can vary due to pre-event conditions, severity of the initiating event, and generator characteristics. Adding blinders or reshaping the characteristic provides greater security than load encroachment or off-setting the zone 2 mho characteristic.
32 Example - Proper Coordination Function The solution in the previous plot is not desirable as it: Results in slow clearing for GSU transformer and high-side bus faults (only one zone of protection is applied) Provides limited coverage for arc resistance In this example the Generator Owner most likely would: Desire two zones of phase distance backup protection Utilize Method 2 to determine whether a less onerous operating point for relay loadability can be obtained
33 Example - Proper Coordination Function A possible solution under investigation and illustrated on the next plot includes: Zone 1 set for generator thermal protection and GSU transformer and high-side bus fault coverage Reach reduced to provide adequate margin against the stressed system condition load point Zone 2 set for system relay backup protection trip dependability Blinders are utilized to meet proposed loadability requirement Use of Method 2, in this example, results in a less onerous operating point for relay loadability
34 Example - Proper Coordination Function 21 - Relay Failure Coverage 34 Zone 2 Relay Setting: pu at Maximum Torque Angle = 85º Zone 1 Relay Setting: pu at Maximum Torque Angle = 85º Method 1 Load Point Method 2 Load Point Determined by Simulation Rated Power Factor Angle = 31.8º Zone 2 Blinders Set at ± 0.4 pu
35 For System Trip Dependability (relay failure coverage) Time Coordination Graph 35 Total time to operate (seconds) Generator Device 21 Set for Relay Failure Protection Line Zone 3 + zone 3 time delay + CB trip time Line Zone 2 + zone 2 time delay + breaker fail time + CB trip time Optional Device 21 zone 1 set to see 120% of generator step up transformer and short of shortest lines zone 1 without including the effects of infeed from other lines/sources Line Zone 1 + breaker fail time + CB trip time Device 21 set to see 120% of longest line connected to generating station bus including the effects of infeed from other lines/sources 80% 100% 125% 150% Distance to fault in % of longest line length
36 Summary of Protection Functions Required for Coordination Function Table 2 Excerpt Function 21 Protection Coordination Considerations Generator Protection Function Transmission System Protection Functions System Concerns 21 Phase distance 21 87B 87T 50BF Both 21 functions have to coordinate Trip dependability Breaker failure time System swings (out-of-step blocking), Protective Function Loadability for extreme system conditions that are recoverable System relay failure Settings should be used for planning and system studies either through explicit modeling of the function, or through monitoring impedance swings at the relay location in the stability program and applying engineering judgment
37 Protection Function Data and Information Exchange Required for Coordination Function Table 3 Excerpt Function 21 Data to be Exchanged Between Entities Generator Owner Transmission Owner Planning Coordinator Relay settings in the R-X plane in primary ohms at the generator terminals One line diagram of the transmission system up to one bus away from the generator high-side bus Feedback on coordination problems found in stability studies Relay timer settings Impedance of all transmission elements connected to the generator high-side bus Total clearing times for the generator breakers Relay settings on all transmission elements connected to the generator high-side bus Total clearing time for all transmission elements connected to the generator high-side bus Total clearing time for breaker failure, for all transmission elements connected to the generator high-side bus
38 Purpose Function 51V 38 Provide backup protection for system faults when the power system to which the generator is connected is protected by time-current coordinated protections.
39 Voltage-Controlled (51V-C) versus Voltage-Restrained (51C-R) Functions 39 Voltage-Controlled Overcurrent Function (51V-C) In the voltage-controlled function, a sensitive low pickup timeovercurrent function is torque controlled by voltage supervision. At normal and emergency operating voltage levels, the voltage supervision is picked up and the function is restrained from operating. Under fault conditions, the voltage supervision will drop out, thereby permitting operation of the sensitive time-overcurrent function. Voltage-Restrained Overcurrent Function (51V-R) The characteristic of a voltage-restrained overcurrent function allows for a variable minimum pickup of the overcurrent function as determined by the generator terminal voltage. At 100 percent generator terminal voltage the overcurrent function will pickup at 100 percent of its pickup setting. The minimum pickup of the overcurrent function decreases linearly with voltage until 25 percent or less when the minimum pickup of the overcurrent function is 25 percent of its minimum pickup setting.
40 Coordination of Generator and Transmission System Function 51V 40 Faults: Generator Owner(s) and Transmission Owner(s) need to exchange the following data: Generator Owner Unit ratings, subtransient, transient and synchronous reactance and time constants Station one line diagrams 51V-C or 51V-R relay type, CT ratio, VT ratio, settings and settings criteria Protection setting criteria Coordination curves for faults in the transmission system two buses away from generator high voltage bus Transmission Owner Protection setting criteria Fault study values of current and voltage for all multi-phase faults two buses away from generator high voltage bus. This includes fault voltages at the high side of the generator step-up transformer. Relay types and operate times for multi-phase faults two buses away from generator high voltage bus. Voltages on the high-side of the generator step-up transformer for extreme system contingencies. Use 0.75 per unit or power flow results for extreme system contingencies.
41 Coordination of Generator and Transmission System Function 51V 41 Loadability For the 51V-C function: The voltage supervision must prevent operation for all system loading conditions as the overcurrent function will be set less than generator full load current. The voltage supervision setting should be calculated such that under extreme emergency conditions (the lowest expected system voltage), the 51V function will not trip. A voltage setting of 0.75 per unit or less is acceptable. For the 51V-R function: The voltage supervision will not prevent operation for system loading conditions. The overcurrent functions must be set above generator full load current. IEEE C recommends the overcurrent function to be set 150 percent above full load current. Coordinate with stator thermal capability curve (IEEE C50.13). Note that 51V functions are subject to misoperation for blown fuses that result in loss of the voltage-control or voltage-restraint.
42 Considerations and Issues Function 51V 42 For trip dependability within the protected zone, the current portion of the function must be set using fault currents obtained by modeling the generator reactance as its synchronous reactance. To set the function to detect faults within the protected zone, the minimum pickup of the current function will be less than maximum machine load current. The protected zone can be defined as: The generator step up transformer (GSU), the high voltage bus, and a portion of a faulted transmission line, which has not been isolated by primary system relaying. The undervoltage element is the security aspect of the 51V-C function. C states: The 51V voltage element setting should be calculated such that under extreme emergency conditions (the lowest expected system voltage), the 51V relay will not trip.
43 Considerations and Issues Function 51V 43 Seventy five percent of rated voltage is considered acceptable to avoid 51V operation during extreme system conditions. A fault study must be performed to assure that this setting has reasonable margin for the faults that are to be cleared by the 51V. Backup clearing of system faults is not totally dependent on a 51V function (or 21 function). The 51V function has limited sensitivity and must not be relied upon to operate to complete an isolation of a system fault when a circuit breaker fails to operate. The 51V has a very slow operating time for multi-phase faults. This may lead to local system instability resulting in the tripping of generators in the area. Phase distance functions should be coordinated with phase distance functions inverse time-current functions should be coordinated with inverse time-current functions. Time coordinating a 51V and a 21 leads to longer clearing times at lower currents.
44 Considerations and Issues Function 51V 44 Special Considerations for Older Generators with Low Power Factors and Rotating Exciters Older low power factor machines that have slower-responding rotating exciters present an additional susceptibility to tripping for the following reasons: The relatively low power factor (0.80 to 0.85) results in very high reactive current components in response to the exciter trying to support the system voltage. The slower response of the rotating exciters in both increasing and decreasing field current in those instances results in a longer time that the 51V element will be picked up, which increases the chances for tripping by the 51V. If it is impractical to mitigate this susceptibility, Transmission Owners, Transmission Operators, Planning Coordinators, and Reliability Coordinators should recognize this generator tripping susceptibility in their system studies.
45 Coordination Procedure Function 51V 45 Voltage-Controlled Overcurrent Function (51V-C) Overcurrent pickup is usually set at 50 percent of generator full load current as determined by maximum real power out and exciter at maximum field forcing. Voltage supervision should be set to dropout (enable overcurrent function) at 0.75 per unit generator terminal voltage or less. Overcurrent function should not start timing until undervoltage supervision drops out. Time coordination must be provided for all faults on the high-side of the GSU including breaker failure time and an agreed upon reasonable margin.
46 Coordination Procedure Function 51V 46 Voltage-Restrained Overcurrent Function (51V- R) The 100 percent setting for the voltage supervision must be at 0.75 per unit terminal voltage or less. Determine an agreed upon margin for trip dependability. The voltage supervision should not drop out for extreme system contingencies. Time coordination must be provided for all faults on the high-side of the GSU including breaker failure time and an agreed upon reasonable margin.
47 Coordination of Generator and Transmission System Function 51V 47 Setting Considerations For the 51V-C function, the voltage supervision must prevent operation for all system loading conditions as the overcurrent function will be set less than generator full load current. A voltage setting of 0.75 per unit or less is acceptable. For the 51V-R function, the voltage supervision will not prevent operation for system loading conditions. The overcurrent function must be set above generator full load current. IEEE C recommends the overcurrent function to be set 150 percent of full load current. (For some applications a higher setting may be necessary.)
48 Example - Proper Coordination Function 51V 48 Generator Short Time Thermal Capability Curve Time in Seconds 51 V-R operating curve with 25% voltage (fastest operating time) 51 V-R range of operation from 100 to 25 % voltage restraint 51 V-R operating curve with full voltage (slowest operating time) For examples with numeric values, see Section of the Technical Reference Document Phase OC on Line - 51 LINE 0.5 s or more margin Current in Amperes Fault Current on Line
49 Summary of Protection Functions Required for Coordination Function 51V 49 Table 2 Excerpt Function 51V Protection Coordination Considerations Generator Protection Function Transmission System Protection Functions System Concerns 51V Voltage controlled / restrained B 51V not recommended when Transmission Owner uses distance line protection functions Short circuit studies for time coordination Total clearing time Review voltage setting for extreme system loading conditions 51V controlled function has only limited system backup protection capability Settings should be used for planning and system studies either through explicit modeling of the function, or through monitoring voltage and current performance at the relay location in the stability program and applying engineering judgment
50 Protection Function Data and Information Exchange Required for Coordination Function 51V 50 Table 3 Excerpt Function 51V Data to be Exchanged Between Entities Generator Owner Transmission Owner Planning Coordinator Provide settings for pickup and time delay (may need to provide relay manual for proper interpretation of the voltage controlled/restrained function) Times to operate, including timers, of transmission system protection Breaker failure relaying times None
51 What is Important to Coordination 51 Settings that Protect the Generator Back Up Protection for Transmission System Protection Worst Case Survivable Condition Calculation for Apparent Impedance with Infeed Current Generator Field Forcing Effects During System Stressed Voltage Conditions Loadability Issues during Stressed System Conditions
52 Settings that Protect the Generator 52 The generator protection set-points are described in the IEEE Guide for AC Generator Protection (C37.102) for both Functions 21 and 51V based on machine - system reactance and characteristics. The previous examples illustrated the set point calculations.
53 Back-Up for Transmission System Protection 53 Providing back-up for transmission system protection requires careful analysis and a balance between tripping security and dependability. These coordination concepts were discussed and illustrated in this presentation. Undesired tripping during system stressed conditions that are survivable must be avoided to maintain a reliable Bulk Electric System.
54 Worst Case Survivable Condition 54 The protection must be set to avoid unnecessary tripping for worst case survivable conditions: Operation of transmission equipment within continuous and emergency thermal and voltage limits Recovery from a stressed system voltage condition for an extreme system event i.e pu voltage at the system high side of the generator step-up transformer Stable power swings Transient frequency and voltage conditions for which UFLS and UVLS programs are designed to permit system recovery When coordination cannot be achieved without compromising protection of the generator, the generator protection setting must be accounted for in system studies.
55 55 Question & Answer Contact: Phil Tatro, System Analysis and Reliability Initiatives
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