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8. Testing Differential Protection (87)

8. Testing Differential Protection (87)

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Te Relay esting Handbook Testing Differential Protection (87) Te Relay esting Handbook Testing Differential Protection (87) Chris Werstiuk Professional Engineer Journeyman Power System Electrician Electrical Technologist Valence Electrical Training Services 7450 w 52nd Ave, M330 Arvada, CO 80002 www.valenceonline.com Although the author and publisher have exhaustively researched all sources to ensure the accuracy and completeness of the informationcontained in this book, neither the authors nor the publisher nor anyone else associated with this publication, shall be liable for any loss, damage, or liability directly or indirectly caused oralleged to be caused by this book. The material contained hereinis not intended to provide specific advice or recommendations for any specific situation. Trademark notice product or corporate names may be trademarks or registered trademarks and are used only for identification, an explanation without intent to infringe. The Relay Testing Handbook: Testing Differential Protection (87) First Edition ISBN: 978-1-934348-17-8 Published By: Valence Electrical Training Ser vices 7450 w 52nd Ave, M330, Arvada, CO, 80002, U.S.A. Telephone: 303-250-8257 Distributed By: www.valenceonline.com Edited by: One-on-One Book Production, West Hills, CA Cover Art: © James Steidl. Image from BigStockPhoto.com Interior Design and Layout:Adina Cucicov, Flamingo Designs Copyright © 2011 by Valence Electrical Training Services. All rights reserved. Neither this book nor any part may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopying, microfilming, and recording, or by any information storage and retrieval system, without permission in writing from the publisher. Published in the United States ofAmerica Author’s Note The Relay Testing Handbookwas created for relay technicians from all backgrounds and provides the knowledge necessary to test most modern protective relays installed over a wide variety of industries. Basic electrical fundamentals, detailed descriptions of protective elements, and generic test plans are combined with examples from real life applications toincrease your confidence in any relay testing situation. A wide variety of relay manufacturers and models are used in the examples to help you realize that once you conquer the sometimes confusing and frustrating man-machine interfaces created by different manufacturers, all digital relays use the same basic fundamentals and most relays can be tested by applying these fundamentals. This package provides a step-by-step procedure for testing the most common differential protection applications used by a variety of manufacturers. Each chapter follows a logical progression to help understand why differential protection is used and how it is applied. Testing procedures are described in detail to ensure that the differential protection has been correctly applied. Each chapter uses the following outline to best describe the element and the test procedures. • • • • • Application Settings Pickup Testing Timing Tests Tips and Tricks to Overcome Common Obstacles We will review techniques to test differential relays with 3 or 6 channels so that readers can test nearly any differential application with any modern test-set. Real world examples are used to describe each test with detailed instructions to determine what test parameters to use and how to determine if the results are acceptable. Thank you for your support with this project, and I hope you find this and future additions of The Relay Testing Handbook to be useful. v Acknowledgments This book would not be possible without support from these fine people Mose Ramieh III Level IV NETA Technician Level III NICET ElectricalTesting Technician Vice President of Power & Generation Testing, Inc. Electrical Guru and all around nice guy. Phil Baker David Snyder Hydropower Test and Evaluation Bonneville Lock and Dam www.nwp.usace.army.mil/op/b/ Lina Dennison Roger Grylls, CET Magna IV Engineering Superior Client Service. Practical Solutions www.magnaiv.com Eric Cameron, B.E.Sc. Manta Test Systems www.mantatest.com vii Table of Contents Author’s Note Acknowledgments v vii Chapter 1 1 Simple Percent Differential (87) Element Testing 1 1. Application 2. Settings A) Enable Setting B) Minimum Pickup (Restrained) C) Tap D) Slope-1 E) Slope-2 F) Breakpoint 1 11 11 11 12 12 12 12 G) Time Delay H) Block 3. Restrained-Differential Pickup Testing A) Test-Set Connections B) Pickup Test Procedure 4. Restrained-Differential Timing Test Procedure 5. Restrained-Differential Slope Testing A) Test-Set Connections B) Slope Test Procedure 6. Tips and Tricks to Overcome Common Obstacles 12 12 13 14 16 18 20 23 24 37 ix The Relay Testing Handbook Chapter 2 39 Percent Differential (87) Element Testing 39 1. Application A) Zones of Protection B) Tap C) Phase-Angle Compensation 2. Settings A) Enable Setting B) Number of Windings C) Phase-Angle Compensation D) MVA E) Winding Voltage F) Minimum Pickup (Restrained) G) Tap H) Slope-1 I) Slope-2 J) Breakpoint K) Time Delay L) Block M) Harmonic Inhibit Parameters 3. Current Transformer Connections 4. 3-Phase Restrained-Differential Pickup Testing A) 3-Phase Test-Set Connections 5. 6. 7. 8. 9. x B) 3-Phase Pickup Test Procedure C) 1-Phase Test-Set Connections D) 1-Phase Pickup Test Procedure Restrained-Differential Timing Test Procedure 3-Phase Restrained-Differential Slope Testing A) Test-Set Connections B) Pre-Test Calculations C) Post-Test Calculations D) Alternate Slope Calculation E) 3-Phase Differential Slope Test Procedure 1-Phase Restrained-Differential Slope Testing A) Understanding the Test-Set Connections B) Test-Set Connections C) 1-Phase Differential Slope Test Procedure Harmonic Restraint Testing A) Harmonic Restraint Test Connections B) Harmonic Restraint Test Procedure with Harmonics C) Harmonic Restraint Test Procedure with Current D) Evaluate Results Tips and Tricks to Overcome Common Obstacles 40 40 41 51 66 66 66 66 68 68 69 69 69 69 69 69 70 70 70 75 77 78 80 82 84 86 93 94 103 107 108 112 112 114 116 118 119 120 122 123 124 Table of Contents Chapter 3 Unrestrained-Differential Testing 1. Settings A) Enable Setting B) Minimum Pickup C) Tap D) Time Delay E) Block 2. Test-Set Connections 3. Simple Pickup Test Procedure 4. Alternate Pickup Test Procedure 5. Timing Test Procedure 6. Tips and Tricks to Overcome Common Obstacles Bibliography 125 125 126 126 126 126 126 126 127 130 133 136 137 139 xi xii Table of Figures Figure 1: Simple Differential Protection Figure 2: Simple Differential Protection with External Fault Figure 3: Simple Differential Protection with External Fault 2 Figure 4: Simple Differential Protection with Internal Fault Figure 5: Simple Differential Protection with Internal Fault 2 Figure 6: Simple Differential Protection with Worst Case CT Error Figure 7: Simple Differential Protection with Worst Case CT Error and External Fault Figure 8: Percentage Differential Protection Schematic Figure 9: Percentage Differential Protection Operating Mechanism Figure 10: Percentage Differential Protection and External Faults Figure 11: Percentage Differential Protection and Internal Faults Figure 12: Percentage Differential Protection and Internal Faults 2 Figure 13: Percentage Differential Protection Characteristic Curve Figure 14: Percentage Differential Protection Characteristic Curve with Minimum Pickup Figure 15: Percentage Differential Protection Dual Slope Characteristic Curve Figure 16: Simple 87-Element Test-Set Connections Figure 17: Simple 3-Phase 87-Element Test-Set Connections Figure 18: Simple 3-Phase 87-Element Test-Set Connections with Six Current Channels Figure 19: Pickup Test Graph Figure 20: GE Power Management 489 Analog Input Specifications Figure 21: GE Power Management 489 Differential and Output Relay Specifications Figure 22: GE Power Management 489 Minimum Trip Time Figure 23: GE Power Management 489 Specifications Figure 24: GE Power Management 489 Slope Test Connection Table Figure 25: GE Power Management 489 Slope Test Connections Example #1 Figure 26: GE Power Management 489 Slope Test Connections Example #2 Figure 27: Simple 87-Element Slope Test-Set Connections Figure 28: Simple 87-Element High Current Slope Test-Set Connections Figure 29: Percentage Differential Protection Dual Slope Characteristic Curve Figure 30: GE 489 Differential Formulas 2 2 3 3 4 5 5 6 6 7 7 8 8 10 11 14 15 15 16 17 18 19 21 21 22 22 23 23 24 25 st Figure 31: Example Characteristic Curve in AmpsTransition with 1 Defined Figure 32: Percentage Differential Protection Dual Slope Characteristic Curve Figure 33: Percentage Differential Protection Dual Slope Characteristic Curve Figure 34: Percentage Differential Protection Dual Slope Characteristic Curve in Amps 26 26 28 30 xiii The Relay Testing Handbook xiv Figure 35: Using Graphs to Determine Pickup Settings Figure 36: GE Power Management 489 Specifications Figure 37: Determine Slope by Rise/Run Calculation Figure 38: Zones of Protection Example Figure 39: 3 Phase Generator Differential Protection Figure 40: 3 Phase Transformer Differential Protection Figure 41: 3 Phase Transformer Differential Protection Using Tap Settings Figure 42: Wye-Delta Transformer Differential Protection Using CT Connections Figure 43: Wye-Delta Transformer Differential Protection Using CT Connections Figure 44: Phase Relationship / Clock Position with Leading Angles Figure 45: Phase Relationship / Clock Position with Lagging Angles Figure 46: Wye-Wye Transformer Figure 47: Wye-Wye Transformer Phasor Diagram Figure 48: Delta-Delta Transformer Connections Figure 49: Delta-Delta Transformer Phasors Figure 50: Wye-Delta Transformer Connections Figure 51: Wye-Delta Transformer Phasor Diagrams Figure 52: Wye-Delta Alternate Transformer Connections Figure 53: Wye-Delta Alternate Transformer Phasor Diagrams Figure 54: Delta-Wye Transformer Connections Figure 55: Delta-Wye Transformer Connections Figure 56: Delta-Wye Alternate Transformer Connections Figure 57: Delta-Wye Alternate Transformer Phasor Diagrams Figure 58: Transformer Nameplate Phase Relationships 31 32 35 40 41 42 43 44 50 53 53 54 55 56 57 58 58 59 59 60 61 62 63 65 Figure 59: Common Phase-Angle Compensation Settings Figure 60: Zones of Protection Example Figure 61: CT Connections Example #1 Figure 62: CT Connections Example #2 Figure 63: GE/Multilin SR-745 Transformer Protective Relay Connections Figure 64: GE T-60 Transformer Protective Relay Connections Figure 65: Beckwith Electric M-3310 Transformer Protective Relay Connections Figure 66: Schweitzer Electric SEL-587 Transformer Protective Relay Connections Figure 67: Schweitzer Electric SEL-387 Transformer Protective Relay Connections Figure 68: Simple 3-Phase 87-Element Test-Set Connections Figure 69: Simple 3-Phase 87-Element Test-Set Connections with Six Current Channels Figure 70: Pickup Test Graph Figure 71: SEL-387E Specifications Figure 72: Simple 87-Element Test-Set Connections Figure 73: Simple 3-Phase 87-Element Test-Set Connections Figure 74: Simple 3-Phase 87-Element Test-Set Connections with Six Current Channels Figure 75: Pickup Test Graph Figure 76: SEL-387E Specifications Figure 77: SEL-387 Differential and Output Relay Specifications Figure 78: SEL-387 Differential Minimum Trip Time 68 71 72 72 73 73 74 74 75 77 77 78 79 80 81 81 83 83 85 85 Table of Figures Figure 79: Common Phase-Angle Compensation Settings Figure 80: Yy12 or Yy0 3-Phase Differential Restraint Test Connections Figure 81: Dd0 3-Phase Differential Restraint Test Connections Figure 82: Dy1 3-Phase Differential Restraint Test Connections Figure 83: Yd1 3-Phase Differential Restraint Test Connections Figure 84: Dy11 3-Phase Differential Restraint Test Connections Figure 85: Yd11 3-Phase Differential Restraint Test Connections Figure 86: Schweitzer Electric SEL-387 Transformer Protective Relay Connections Figure 87: 3-Phase Restrained-Differential Slope Test-Set Connections Figure 88: Percentage Differential Protection Dual Slope Characteristic Curve Figure 89: SEL-387 Slope-1 Differential Formulas Figure 90: SEL-387 Definition of IOP and IRT Figure 91: SEL-387 Slope-2 Differential Formulas Figure 92: Percentage Differential Protection Dual Slope Characteristic Curve in Amps Figure 93: Using Graphs to Determine Pickup Settings Figure 94: Determine Slope by Rise/Run Calculation Figure 95: YDac Transformer Connection Figure 96: Transformer Relay Connections for Single-Phase Differential Testing Figure 97: Schweitzer Electric SEL-387 Transformer Protective Relay Connections Figure 98: 1-Phase Restrained-Differential Slope Test-Set AØ Yd1 Connections Figure 99: 1-Phase Restrained-Differential Slope Test-Set BØ Yd1 Connections Figure 100: 1-Phase Restrained-Differential Slope Test-Set CØ Yd1 Connections Figure 101: Transformer Inrush Waveform Figure 102: Simple 3-Phase 87-Element Test-Set Connections 87 88 89 90 91 91 92 93 94 95 96 96 100 101 102 107 112 113 114 114 115 115 118 119 Figure 103: Simple 3-Phase, Higher Current 87-Element Test-Set Connections Figure 104: Simple Differential Protection with Worst Case CT Error and External Fault Figure 105: Simple 87U-Element Test-Set Connections Figure 106: Parallel 87U-Element Test-Set Connections Figure 107: Parallel 87U-Element Test-Set Connections with Equal W_CTC Settings Figure 108: Transformer Relay Connections for Single-Phase Differential Testing Figure 109: 1-Phase Differential Test-Set AØ Yd1 Connections Figure 110: SEL-387E Specifications Figure 111: SEL-387 Differential Element Specifications Figure 112: Preferred SEL-387 Output Contact Specifications 120 125 127 128 128 129 129 131 135 136 xv Chapter 1 Simple Percent Differential (87) Element Testing Differential protection (87) is applied to protect equipment with high replacement costs and/or long replacement/repair times, or a group of equipment which is integral to the electrical system. 87-Elements are selective and will only operate when a fault occurs within a specified zone of protection with no inherent time delay. There are several methods to apply differential protection but they are all designed to achieve the same basic principal; trip for faults within the zone of protection and ignore faults outside of the zone of protection. The zone of protection is defined by strategic placement of current transformers (CTs) that measure the current entering and exiting the zone. If the difference between currents is larger than the 87-Element setpoint, the relay will trip. Percent differential protection is the most commonly applied differential element and this chapter will lay the foundation for understanding most differential protection schemes. This chapter only discusses the simplified differential protection typically found in generator, motor, or other applications where the voltage and CT ratios are the same on both sides of the protected device. All descriptions are made on a single-phase basis and you should keep in mind that identical configurations exist for the other two phases in a three-phase system. We will discuss complex differential protection typically installed for transformers in the next chapter. 1. Application Differential protection operates on the principle that any current entering the protected zone must equal the current leaving the protected zone, and that a difference between the two currents is caused by an internal fault. Differential CTs are often strategically installed to provide overlapping protection of circuit breakers and, therefore, a generator differential scheme may include other equipment such as PTsand circuit breakers. 1 The Relay Testing Handbook The following figure displays a simplified version of differential protection that would typically be applied to a generator or bus. The equipment being protected in this example would be connected between CT1 and CT2 which defines the differential zone of protection. The current flows from left to right in this system and enters the polarity mark of CT1. The CT secondary current follows the circuit and flows through the Iop coil from the bottom to top. Simultaneously, the current enters the non-polarity mark of CT2 and the CT secondary current flows through the Iop coil from top to bottom. If the CTs are operating perfectly and have the same CT ratio, the net Iop current would be zero amps because the two currents cancel each other out. Early differential elements were simple overcurrent devices and the Iop coil would have a relatively low setting. 100 A 100:5 CT1 G 100:5 CT2 Iop = 0.0 A I1=5.0A I2=5.0A Figure 1: Simple Differential Protection The next figure displays an external fault in an ideal world. The current entering the zone of protection equals the current leaving the zone and cancel each other out just like the first example. If the Iop coil was a simple overcurrent element, nothing would happen because zero amps flow though the Iop coil. 1000 A 100:5 CT1 G 100:5 CT2 FAULT Iop = 0.0 A I1=50.0A I2=50.0A Figure 2: Simple Differential Protection with External Fault 2 Chapter 1: Simple Percent Dif ferential (87) Element Testing The next figure shows a fault in the opposite direction. The current-in equals the current-out and cancel each other out. The Iop element does not operate. 1000 A 100:5 CT1 G FAULT 100:5 CT2 Iop = 0.0 A I1=50.0A I2=50.0A Figure 3: Simple Differential Protection with External Fault 2 The next figure displays an internal fault with Source 1 only. In this scenario, current flows into CT1 and the secondary current flows through Iop, bottom to top. There is no current flowing through CT2 and, therefore, nothing to cancel the CT1 current. If the CT1 current is greater than the Iop setting, the Iop element will trip. 1000 A 100:5 CT1 100:5 CT2 FAULT G Iop = 50.0 A I1 = 50.0 A Figure 4: Simple Differential Protection with Internal Fault 3 The Relay Testing Handbook The next figure displays an internal fault with sources on both ends. Current flows into CT1 and its secondary current flows through Iop from bottom to top. Current flows through CT2 and its secondary current flows through Iop from bottom to top also. In this case the currents add together instead of canceling each other out and the Iop element will trip if the combined currents are larger than the Iop trip setting. 1000 A 1000 A 100:5 CT1 100:5 CT2 FAULT G Iop = 100.0 A I1=50.0A I2=50.0A Figure 5: Simple Differential Protection with Internal Fault 2 In an ideal world, differential current is a simple overcurrent relay connected between two or more CTs as shown in previous figures. Unfortunately, we do not live in an ideal world and no two CTs will produce exactly the same output current even if the primary currents are identical. In fact, protection CTs typically havea 10% accuracy class which can cause problems with the protection scheme described previously. The news gets worse when you also consider that CT accuracy can jump to 20% when an asymmetrical fault is considered. The difference between CT operating characteristics is called CT mismatch and the effects of CT mismatch are displayed in the following figures. This is a worst case scenario with nominal current. 100A flows through CT1, and the secondary current with -10% error equals 4.5A (5.0A − 5.0A ×0. 10  ) flowing through Iop from bottom to top. 100A flows through CT2, and the secondary current with +10% error equals 5.5A ( 5.0A + 5.0A × 0.10  ) flowing through Iop from top to bottom. The difference between the two CT secondaries is 1.0A. The Iop element must be set larger than 1.0A or the relay will trip under normal load conditions assuming a worst case CT mismatch. 4 Chapter 1: Simple Percent Dif ferential (87) Element Testing 100 A 100:5 CT1 G 100:5 CT2 Iop = 1.0 A I1=4.5A I2=5.5A Figure 6: Simple Differential Protection with Worst Case CT Error The next figure displays an external fault with the worst case CT mismatch. As in our previous example, the CT1 secondary current with -10% error is 45A flowing through the Iop from bottom to top. The CT2 secondary current with +10% error is 55A flowing through Iop from top to bottom. The differential current is 10A and the Iop element would incorrectly trip for a fault outside the zone using the previouslydefined setting of 1.0A. This element would haveto be set greater than 10A to prevent nuisance trips if a fault occurs outside the zone of protection. This setting is very high and any internal fault would need to cause greater than 200A (2x the rated current for a single source system) or 100A (dual source system) of fault current to operate the differential element. This setting does not appear to limit equipment damage very well and a new system was developed to provide more sensitive protection and prevent nuisance trips for external faults. 1000 A 100:5 CT1 G 100:5 CT2 FAULT Iop = 10.0 A I1=45.0A I2=55.0A Figure 7: Simple Differential Protection with Worst Case CT Error and External Fault 5 The Relay Testing Handbook This new system adds a restraint coil (Ir) along with the existing operate coil (Iop)in the circuit as shown in Figure 8. This Ir coil provides counter-force in electro -mechanical relays as shown in Figure 9 which pulls the trip contacts apart. The Ir coil force is directly related to the average of the I1 and I2 currents. The Iop coil attempts to pull the trip contacts together and the coil force is directly related to the Iop current. The two coils are designed so the Iop coil will be able to close the contacts if the ratio of Iop to Ir exceeds the relay’s slope setting. Therefore, any slope setting is a ratio of Iop to Ir. We will define current flowing through the Iop coil as "operate current" and current flowing through the Ir current as the "restraint current" for the rest of this book. 100 A 100:5 CT1 G 100:5 CT2 Iop = 1.0 A I1=4.5A I2=5.5A Ir = (4.5 A + 5.5 A)/2 Ir = 5.0 A Figure 8: Percentage Differential Protection Schematic Ir Iop Figure 9: Percentage Differential Protection Operating Mechanism With this new system, the designer chooses a slope setting instead of a fixed current and the relay will adjust the pickup setting tothe system parameters. Our example slope setting willbe 25% for the following figures which repeat the previous fault simulations with the new design. Figure 10 displays normal operating conditions. The CT1 secondary current (4.5A) flows through the Iop coil as before. The CT2 current (5.5A) flows through Iop in opposition and the 1.0A differential current energizes the Iop coil which tries to close the trip contact. The 6 Chapter 1: Simple Percent Dif ferential (87) Element Testing trip contact does not close because one-half of the restraint coil has 4.5A of CT1 current and the other half has 5.5A of CT2 current. The average of these two currents creates the Ir force holding the contacts open. In this case the average of the two CT currents is 5.0A. The ratio of operate coil current and restraint coil current is 20% (10A = 0.2,0.2 × 100 = 20% ). The pickup 50A setting of this relay is 25% so the restraint coil is applying more force than the operate coil and the relay will not trip. 100 A 100:5 CT1 100:5 CT2 G Iop = 1.0 A I1=4.5A I2=5.5A Ir = (4.5 A + 5.5 A)/2 Ir = 5.0 A slope = 100 x Iop / Ir slope = 100 x 1.0 / 5.0 slope = 20% < Slope setting 25% NO TRIP Figure 10: Percentage Differential Protection and External Faults The next figure displays an internal fault with only one source. The relay trips in this scenario due to the 200% slope. 1000 A 100:5 CT1 G FAULT 100:5 CT2 Iop = 45.0 A I1 = 45.0 A Ir = (45 A + 0.0 A)/2 Ir = 22.5 A slope = 100 x Iop / Ir slope = 100 x 45.0 / 22.5 slope = 200% > Slope setting 25% TRIP Figure 11: Percentage Differential Protection and Internal Faults 7 The Relay Testing Handbook The next figure displays an internal fault with two sources. The relay trips in this scenario due to the 200% slope. 1000 A 1000 A 100:5 CT1 FAULT 100:5 CT2 G Iop = 100.0 A I1=45.0A I2=55.0A Ir = (45 A + 55 A)/2 Ir = 50 A slope = 100 x Iop / Ir slope = 100 x 100 / 50 slope = 200% > Slope setting 25% TRIP Figure 12: Percentage Differential Protection and Internal Faults 2 The characteristic curve of this element is shown in the following figure. The relay will trip if the ratio of Iop to Ir is plotted above the line and will not trip if the ratio falls below the line. Differential Protection 25% Characteristic Curve 3.0 ) 2.5 p o (I t 2.0 n e r r u 1.5 C e t a 1.0 r e p O 0.5 Trip Area Restraint Area 0.0 0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0 8.0 9.0 10.0 11.0 12.0 Restraint Current (Ir) Figure 13: Percentage Differential Protection Characteristic Curve 8 Chapter 1: Simple Percent Dif ferential (87) Element Testing Most relays have a Tap setting that defines the normal operating current based on the rated load of the protected equipment, the primary voltage, and the CT ratio. For example, imagine a 3-phase, 4160V, 600 kW generator. Using the standard 3-phase power formula, we can determine that the rated primary current is 83.27A. Power = P-P Volts × Amps × 3 600000W = Amps ( 4160V × 3 ) = 83.27A The secondary current at full load using 100:5 CTs would be 4.16A CTSEC AmpsSEC = CTPRI AmpsPRI AmpsSEC 5A = 100A 83.27A AmpsSEC = 5A × 83.27A =4.16A 100A We can combine the two formulas to determine the calculated Tap setting in one step. AmpsSEC = CTSEC × Power P-P Volts × 3 ×CT PRI The Tap setting could also be considered the per-unit current of the protected device and, if the Tap settings exist, is the basis for all differential calculations. If we were to zoom in on the srcin of the graph in Figure 13, we would see that it takes very little operate current to trip this element at low power levels. Any induced current, noise, or excitation current could cause this element to trip under these normal conditions. One common situation occurs when the transformer is energized with no connected load. There will be some excitation current on the primary side of the transformer and no current on the secondary side. This is the definition of a differential fault, but it is a normal condition, and we do not want the 87-Element to operate under normal conditions. 9 The Relay Testing Handbook A new setting called Minimum Pickup is introduced to ensure that the 87-Element will trip under fault conditions and ignore normal mismatch at low current levels. This setting sets the minimum amount of current that must be present before the 87-Element will operate. This setting is sometimes in secondary amps for simple differential applications, but it is more commonly set as a percentage or multiple of the Tap setting and is typically set at0.3 times the Tap setting. The differential characteristic curve changes when the Minimum Pickup setting is applied as shown in Figure 14. Notice the flat line between 0 and 1.00 Restraint Current at the beginning of the curve which represents the Minimum Pickup setting (0.3 x Tap current). Also notice that the Operate and Restraint currents are plotted as Multiples of Tap and not amps. Differential Protection 25% Characteristic Curve 2.0 1.8 1.6 t n e r r u C e t a r e p O 1.4 P 1.2 A T 1.0 )x p 0.8 Io ( Trip Area Restraint Area 0.6 0.4 0.2 0.0 0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0 8.0 Restraint Current (Ir) x TAP Figure 14: Percentage Differential Protection Characteristic Curve with Minimum Pickup As the fault current increases, the chance of CT saturation or other problems occurring dramatically increase which can cause up to a 20% error during asymmetrical faults. Because digital relays use programming instead of components for their pickup evaluations, we can add a second slope setting to be used when the restraint current exceeds a manufacturer or userdefined level of current. This second slope has ahigher setting, and the differential protection will be less sensitive during high-level external faults. The transition between the two slope settings is called the breakpoint or knee and is predefined by the manufacturer in some relays oruser-defined in others. The breakpoint is set in multiples of Tap. The differential characteristic curve with a Minimum Pickup and two slope settings is shown in the followingfigure. 10 Chapter 1: Simple Percent Dif ferential (87) Element Testing Differential Protection 25%/40% Characteristic Curve 3.00 Trip Area 2.50 t n e r r u C e t a r e p O P 2.00 A T )x 1.50 p o I ( 1.00 Slope 2 Slope 1 Restraint Area 0.50 0.00 0.00 1.00 2.00 3.00 4.00 5.00 6.00 7.00 8.00 Restraint Current (Ir) x TAP Figure 15: Percentage Differential Protection Dual Slope Characteristic Curve 2. Settings The most common settings used in 87-Elements are explained below: A) Enable Setting Many relays allow the user to enable or disable settings. Make sure that theelement is ON, or the relay may prevent you from entering settings. If theelement is not used, the setting should be disabled or OFF to prevent confusion. Some relays will also have “Latched” or ‘Unlatched” options. A Latched option indicates that the output contacts will remain closed after a trip until a reset is performed and acts as a lockout relay. Unlatched indicates that the relay output contacts will open when the trip conditions are no longer present. B) Minimum Pickup (Restrained) The Minimum Pickup setting is used to provide more stability to the differential element by requiring a minimum amount of current to flow before the differential element will operate. This minimum operate current is used to prevent nuisance trips due to noise or metering errors at low current levels. This setting should be set around 0.3 times the nominal or Tap setting of the protected device. 11 The Relay Testing Handbook C) Tap The Tap setting defines the normal operate current based on the rated load of the protected equipment, the primary voltage, and the CT ratio. This setting is used as the per-unit operate current of the protected device and most differential settings are based on the Tap setting. Verify the correct Tap setting using the following formula. AmpsSEC = CTSEC × Power P-P Volts × 3 ×CT PRI D) Slope-1 The Slope-1 setting sets the ratio of operate current to restraint current that must be exceeded before the 87-Element will operate. The slope setting is typically set at 20-30%. E) Slope-2 The Slope-2 setting sets the ratio of operate current to restraint current that must be exceeded before the 87-Element will operate if the restraint current exceeds a pre-defined or user-defined break point between Slope-1and Slope-2. F) Breakpoint This setting defines whether Slope-1 or Slope-2 will be used for the differential calculation. The Breakpoint is defined as a multiple of Tap and if the restraint current exceeds the Breakpoint setting, the 87-Element will use Slope-2 for its calculation. G) Time Delay The Time Delay setting sets a time delay between an 87-Element pickup and trip. This is typically set at the minimum possible setting, but can be set as high as 3 cycles for maximum reliability on some relays. H) Block The Block setting defines a condition that will prevent the differential protection from operating such as a status input from another device. This setting is rarely used. If enabled, make sure the condition is not true when testing. Always verify correct blocking operation by operating the end-device instead of a simulation to ensure the block has been correctly applied. 12 Chapter 1: Simple Percent Dif ferential (87) Element Testing 3. Restrained-Differential Pickup Testing Performing simple differential pickup testing is very similar to the test procedure for overcurrent protection with a few extra phases to test. Apply a current in one phase, and raise the current until the element operates. Repeat for all affected phases. As usual, you must determine what the expected result should be before performing any test. Record the Pickup and Tap settings. If the relay does not have a Tap setting, refer to the manufacturer’s literature to determine if the relay uses some other nominal setting such as rated secondary current (5A usually). Multiply the Pickup and Tap settings to determine the Minimum Pickup in amps. The Tap setting from our previous example is 4.16A and the Pickup setting is 0.3. The expected pickup current for this example would be 1.248A. ( 4.16A × 0.3 = 1.248A ) We will use a GE Power Management 489 relay with the following Phase Differential settings for the rest of the tests in this chapter. • • • • • • Phase Differential Trip = Unlatched Assign Trip Relays = 1 Differential Trip Minimum Pickup = 0.1 x CT Differential Trip Slope-1 = 20% Differential Trip Slope-2 = 80% Differential Trip Delay = 0 cycles The Minimum settingindicates for this relay is 0.1 x CT thiscurrent relay does notinhave a Tapactual setting. The CTPickup designation the nominal CTbecause secondary (5.0A North America and 1.0A in Europe). The expected Minimum Pickup is 0.5A. ( 0.1 × CT= ×0.1 5.0 = A 0.5 A ) If the pickup test results are significantly higher or lower than the expected result,efer r to the next chapter’s instructions for pickup testing because the algorithm for the relay under test probably uses a complex equation for restraint current and correction factors will apply. 13 The Relay Testing Handbook A) Test-Set Connections The most basic test-set connections use only one phase of the test-set with a test lead change between every pickup test. After the Winding-1 A-phase pickup test is performed, move the test leads from Winding-1 A-Phase amps to B-Phase amps and perform the test again. Repeat until all enabled phases are tested on allenabled windings. RELAY INPUT RELAY AØ PU WINDING 1 A Phase Input=Pickup A Phase Amps + RELAY TEST SET + + + + + B Phase Amps C Phase Amps M a g n i t ud e C1 Amps AØTestAmps P h a s eA ng l e Frequency 0° Test Hz C2 Amps C3 Amps WINDING 2 A Phase Amps B Phase Amps C Phase Amps Element Output + + + + + Timer Input Alternate Timer Connection + DC Supply Element Output + Timer Input Figure 16: Simple 87-Element Test-Set Connections You can also connect all three phases to one winding and change output channels instead of changing leads. After all Winding-1 tests are completed, move the test leads to Winding-2 and repeat. 14 Chapter 1: Simple Percent Dif ferential (87) Element Testing TEST #1 RELAY INPUT TEST #2 RELAY INPUT AØ PU TEST #3 RELAY INPUT BØ PU CØ PU RELAY TEST SET RELAY M ag n i t u d e WINDING 1 A Phase Amps B Phase Amps C Phase Amps WINDING 2 A Phase Amps B Phase Amps C Phase Amps Element Output + + + + + + P h a seAn g l e Frequency C1 Amps AØTestAmps 0° C2 Amps BØTestAmps 0° TestHz C3 Amps CØTestAmps 0° TestHz Test Hz + + + + + Alternate Timer Connection +DC Supply Timer Input - Element Output Timer Input + Figure 17: Simple 3-Phase 87-Element Test-Set Connections If your test-set has six available current channels, you can use the following connection diagram and change the output channel for each test until all pickup values have been tested. TEST #1 RELAY INPUT TEST #2 RELAY INPUT TEST #3 RELAY INPUT TEST #4 RELAY INPUT TEST #5 RELAY INPUT TEST #6 RELAY INPUT A1Ø PU B1Ø PU C1Ø PU A2Ø PU B2Ø PU C2Ø PU RELAY WINDING 1 A Phase Amps B Phase Amps C Phase Amps RELAY TEST SET + + + + + + + + + + + + Mag nitu de Ph as e An g le Frequency C1 Amps A1ØTestAmps 0° Test Hz C2 Amps B1ØTestAmps 0° TestHz C3 Amps C1ØTestAmps 0° TestHz C4 Amps A2ØTestAmps 0° TestHz C5 Amps B2ØTestAmps 0° TestHz C6 Amps C2Ø Test Amps WINDING 2 A Phase Amps B Phase Amps C Phase Amps 0° TestHz Alternate Timer Connection +DC Supply - Element Output + + Timer Input Element Output + Timer Input Figure 18: Simple 3-Phase 87-Element Test-Set Connections with Six Current Channels 15 The Relay Testing Handbook B) Pickup Test Procedure Use the following steps to determine pickup: 1. Determine how you will monitor pickup and set the relay accordingly (if required). (Pickup indication by LED, output contact, front panel display, etc…See previous packages of The Relay Testing Handbookfor details.) 2. Set the fault current 5% higher than the pickup setting. For our example, set the fault current at 0.525A for an element with a 0.5A setpoint. Make sure pickup indication operates. 3. Slowly lower the current until the pickup indication is off. Slowly raise current until pickup indication is fully on. (Chattering contacts or LEDs ar e not considered pickup.) Record the pickup values on your test sheet. The following graph displays the pickup procedure. 5A ELEMENT PICK-UP 4A 3A 2A PICKUP SETTING 1A STEADY-STATE PICKUP TEST Figure 19: Pickup Test Graph 4. Compare the pickup test result to the manufacturer’s specifications and calculate the percent error as shown in the following example. The 87-Element pickup setting is 0.5A and the measured pickup was 0.508A. Looking at the “OUTPUT AND NEUTRAL END CURRENT INPUTS” specification in Figure 20, we see that the acceptable metering error is 0.05A. (“ Accuracy: @ < 2 x CT: ± 0.5% of 2 x CT” = 0.5% ×10 A = 0.05A ). The difference between the test result and setting is 0.008A ( 0.508A − 0.500A ). We can immediately consider it acceptable as it falls within the metering accuracy specifications in Figure 20. 16 Chapter 1: Simple Percent Dif ferential (87) Element Testing OUTPUT AND NEUTRAL END CURRENT INPUTS Accuracy: @<2xCT:±0.5%of2xCT @ > 2 x CT: ± 1% of 20 x CT OUTPUT RELAYS OperateTime: 10ms PHASE DIFFERENTIAL Pickup Accuracy: as per Phase Current Inputs Timing Accuracy: +50ms @ 50/60 Hz or ± 0.5 % of total time Figure 20: GE Power Management 489 Analog Input Specifications Using these two sections, we can calculate the manufacturer’s allowable per cent error. Use “Accuracy: @ < 2 x CT: ± 0.5% of 2 x CT” from the specifications in Figure 20 because the applied current is less than 2x CT (20A), the allowable percent error is 10%. Maximum Accuracy Tolerance × 100 = Allowable Percent Error Setting 0.5% × (2 × CT) × 100 = Allowable Percent Error 0.5A 0.005 × (2 × 5A) × 100 = Allowable Percent Error 0.5A 0.005 × 10A × 100 = Allowable Percent Error 0.5A 0.05A × 100 = Allowable Percent Error 0.5A 10% Allowable Percent Error The measured percent error can be calculated using the percent error formula below. Actual Value - Expected Value × 100 = Percent Error Expected Value 0.508A - 0.500A × 100 = Percent Error 0.500A 1.6% Error 5. Repeat the pickup test for all phase currents that are part of the differential scheme. 17 The Relay Testing Handbook DIFFERENTIAL TEST RESULTS PICK UP 0.1 SLOPE 1 10% SLOPE 2 20% TIME DELAY 0 MINIMUM PICK UP TESTS (Amps) PHASE A PHASE B PHASE C MFG % ERROR W1 PICKUP 0.508 0.508 0.505 0.500 1.60 1.60 1.00 W2 PICKUP 0.500 0.506 0.508 0.500 0.00 1.20 1.60 W3 PICKUP NA NA NA 0.500 4. Restrained-Differential Timing Test Procedure The timing test procedure is very straightforward. Apply a single-phase current 10% greater than the Minimum Pickup setting into each input related to the percent differential element and measure the time between the applied current and the relay trip signal. As with all tests, we first must discover what an acceptable result is. Use Figure 21 to determine the acceptable tolerances from the manufacturer’s specifications. Figure 21: GE Power Management 489 Differential and Output Relay Specifications The time delay setting for our example is 0 cycles which means that there is no intentionaldelay. However, there are software and hardware delays built into the relay that must be accounted for as shown in Figure 22 that state that the maximum allowable time is 60ms or 3.6 cycles. 18 Chapter 1: Simple Percent Dif ferential (87) Element Testing R EA S ON DELAY Phase Differential Timing Accuracy (Software) Output Relay Operate Time (Hardware) Total Time 50ms 10ms 60ms or 3.6 cycles Figure 22: GE Power Management 489 Minimum Trip Time Perform a timing test using the following steps: 1. Connect the test-set input(s) to the relay output(s) that are programmed to operate when the restrained-differential relay operates. 2. Configure your test-set to start a timer when current is applied and stop the timer and output channels when the appropriate input(s) operate. 3. Choose a connection diagram from Figures 16-18 on pages 14-15. Set a single-phase current at least 10% higher than the Minimum Pickup setting. Minimum Pickup × 110% = × 0.5A = 1.1 0.55A 4. Run the test plan on the first phase related to restrained-differential. Record the test results. 5. Repeat on all phases related to the restrained-differential. RESTRAINED DIFFERENTIAL TIMING TESTS (cycles) WINDING TEST W1 0.55A W2 0.55A W3 NA AP H A S E( c y ) 2.410 2.45 NA BPH A S E( c y ) C PH A S E ( c y ) 2.490 2. 44 NA 2.500 2.48 NA MFG( c y cl e s ) %E R R O R 3.600 OK OK OK 3.600 OK OK OK NA 19 The Relay Testing Handbook 5. Restrained-Differential Slope Testing Differential slope testing is one of the most complex relay tests that can be performed and requires careful planning, a good understanding of the differential relay’s operating characteristics, and information from the manufacturer regarding the relay’s characteristics. The instructions for this section use single-phase test techniques that will only work when applied to simple differential relays with identical CT ratios and no phase-angle shift between windings. The following test plan also assumes a simple slope calculation as described previously, butfalldifferent relays mayrange use different to determine slope. If your test results do not into an acceptable with this methods test procedure, refer to the manufacturer’s literature for the relay’s slope calculation and apply the manufacturer’s formula to the results. If the results still do not match the expected results, refer to the Restrained-Differential Slope Testing section of the next chapter for more details. A simple differential slope test is performed by choosing a phase (AØ for example) and applying current into that phase for two windingsthat are part of the differential element. Let’s look at the manufacturer’s recommended connection diagram shown in Figure 23 for the GE Power Management 489 relay in our example. Follow the AØ primary buss through the neutral CTs (Phase a) then follow the secondary CT to terminal H3. This is where we will connect the first current from our test-set. Connect the neutral of the test-set current channel to G3 by following the other side of the CT to its relay terminal. Keep following the primary buss through the generator to the other CT and then follow the secondary to terminal G6.toThis the neutral of the CTs soCT we to will connectH6 the test-set’s second current-channel-neutral G6.isFollow the other side ofthe terminal which is where we will connect the second current-channel from the test-set. Follow the other phases to determine these connections when testing B or C phases. 20 Chapter 1: Simple Percent Dif ferential (87) Element Testing Figure 23: GE Power Management 489 Specifications TEST SET Channel1+ Channel1Channel2+ Channel2- APHASE 489H3 489G3 489H6 489G6 - BPHASE 489H4 489G4 489H7 489G7 - CPHASE 489H5 489G5 489H8 489G8 - Figure 24: GE Power Management 489 Slope Test Connection Table 21 The Relay Testing Handbook Notice that the polarity marks of the CT’s are in opposite directions. If we were to apply both currents into the relay at the same phase-angle, all of the applied current would be differential or operate current. We would not be able to perform a slope test because the slope will always be 200% as shown in Figure 25. CHANNEL 1 0º @ 5A CHANNEL 2 G FAULT 0º @ 5A Iop = 10.0 A G3 G6 I1=5.0A Ir = (5 A + 5 A)/2 Ir = 5 A I2=5.0A H3 H6 Slope = Iop / Ir Slope = 10.0A / 5.0 A = 200% Figure 25: GE Power Management 489 Slope Test Connections Example #1 If this test was performed on a bench, the easy solution would be to switch the H3-G3or H6-G6 connections. This quick fix isn’t always possible when testing installed relays so we change the Channel 2 phase-angle to 180º to achieve the same result. If you look at Figure 26 car efully, you’ll see that this is the normal running configuration for the GE 489 relay. CHANNEL 1 0º @5A CHANNEL 2 G 180º @5A FAULT Iop = 0.0 A G3 G6 I1=5.0A Ir = (5 A + 5 A)/2 Ir = 5 A I2=5.0A H3 H6 Slope = Iop / Ir Slope = 0.0A / 5.0 A = 0% Figure 26: GE Power Management 489 Slope Test Connections Example #2 22 Chapter 1: Simple Percent Dif ferential (87) Element Testing A) Test-Set Connections The test-set connections for a simple slope test are as follows. Some tests require large amounts of current which will require the connection in Figure 28. W1 RELAY INPUT W2 RELAY INPUT C1 Amps C2Amps RELAY RELAY TEST SET Ma g n i t u d e WINDING 1 + A Phase Amps B Phase Amps Pha s e A n g l e Frequency + + + + + C Phase Amps C1 Amps W1TestAmps 0° C2 Amps W2TestAmps 180° C3 Amps 0.00A Test Hz TestHz 0° Test Hz WINDING 2 A Phase Amps + + B Phase Amps + C Phase Amps Element Output + + Timer Input Alternate Timer Connection + DC Supply - Element Output + Timer Input Figure 27: Simple 87-Element Slope Test-Set Connections W1 RELAY INPUT C1 Amps C2 Amps W2 RELAY INPUT C3Amps RELAY RELAY TEST SET Ma g n it u d e WINDING 1 + A Phase Amps B Phase Amps + + + + C Phase Amps P h a s eA n g l e Frequency + C1 Amps W1TestAmps/2 C2 Amps W1TestAmps/2 C3 Amps 0° Test Hz 0° W2TestAmps TestHz 180° TestHz WINDING 2 A Phase Amps + + B Phase Amps + C Phase Amps Element Output + + Timer Input Alternate Timer Connection DC Supply + Element Output + Timer Input Figure 28: Simple 87-Element High Current Slope Test-Set Connections 23 The Relay Testing Handbook B) Slope Test Procedure The test procedure seems straightforward. Apply equal current into Winding-1 and Winding-2 with a 180º phase shift between windings, and raise one current until the relay operates. The difficult part of this procedure is determining what starting current to apply and what the expected pickup should be. We can start by re-plotting the characteristic curve shown in Figure 29 using the following relay settings. Phase Differential Trip = Unlatched • • Assign Trip Relays = 1 Differential Trip Minimum Pickup = 0.1 x CT Differential Trip Slope-1 = 20% Differential Trip Slope-2 = 80% Differential Trip Delay = 0 cycles • • • • Differential Protection 20/80% Characteristic Curve 3.00 Trip Area 2.50 t n e r r u C e t a r e p 2.00 Slope 2 P A T 1.50 )x p Io ( 1.00 O Slope 1 Restraint Area 0.50 0.00 0.00 1.00 2.00 3.00 4.00 5.00 6.00 7.00 8.00 Restrain Current (Ir) x TAP Figure 29: Percentage Differential Protection Dual Slope Characteristic Curve We first need to change the restraint and operate current values to amps instead of multiples of Tap. Then we can calculate thetransition point between the Minimum Pickup and Slope-1 operation. The Minimum Pickup is 0.50A 0.1 ( × CT ) as we calculated earlier in this chapter. Slope-1 will be enabled when the operate current is greater than the minimum pickup. Different relays have different slope calculations and we can refer to the GE 489 relay instruction manual to determine the relay’s differential calculation as shown in Figure 30. 24 Chapter 1: Simple Percent Dif ferential (87) Element Testing FUNCTION: The 489 percentage differential element has dual slope characteristic. This allows for very sensitive settings when fault current is low and less sensitive settings when fault current is high, more than 2 x CT, and CT performance may produce erroneous operate signals. The minimum pickup value sets an absolute minimum pickup in terms of operate current. The delay can be fine tuned to an application such that it still responds very fast, but rides through normal operational disturbances. The Differential element for phase A will operate when: IOperate>k×I IOperate=I I- IRestraint = Restraint A a IA - Ia 2 where: IOperate = operate current IRestraint = restraint current k = characteristic slope of differential element in percent (Slope 1 if IR < 2 X CT, Slope 2 if I R > = 2 X CT) IA = phase current measured at the output CT Ia = phase current measured at the neutral end CT Differential elements for phase B and phase C operate in the same manner. Figure 30: GE 489 Differential Formulas Notice that the Ir current (IRestraint) is defined as IW1 + IW 2 2 I A + Ia 2 which can be translated into for our terminology. The bars on either side of each current indicate that we use absolute values when calculating the restraint current. We can drop the bars and re-define Ir as IW1 + IW 2 . The Iop current (IOperate) is defined as I A − Ia which can be translated into 2 for our calculations. The bars above each current indicate a vectorsum calculation and we can redefine the Iop calculation as IW1 − IW 2 because our vectors will always be 180º apart. IW 1 − IW 2 Use the first IOperate formula to calculate the transition between Minimum Pickup and Slope-1 where Slope-1 begins when Iop exceeds the Minimum Pickup setting (0.5 A) defined previously. Notice that our generic formula on the right also works for this relay. Based on these calculations, our restraint current must be greater than 2.505A to test Slope-1. Iop > k ×Ir 20% = 100 × 0.501 Ir 0.501 = 20% × Ir Ir = 0.501 = 2.505 0.2 Ir = 100 × 0.501 = 50.1 = 2.505 20% 20 Ir =2.505 A 25 The Relay Testing Handbook Figure 31 displays the revised characteristic curve so far. Differential Protection 20% Characteristic Curve 35.0 t n e rr u C e t ra e p O 30.0 Trip Area ) s 25.0 p m A 20.0 n i p 15.0 Io ( Slope 1 Transition 1 10.0 Restraint Area 5.0 Min 0.0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 Restraint Current (Ir in Amps) Figure 31: Example Characteristic Curve in Amps with st1Transition Defined We also need to determine the maximum restraint current before we accidentally start Iop ) testing Slope-2 when testing Slope-1. We can use the slope formula Slope ( (%) = 100 × Ir to calculate the restraint current (Ir) at the transition pointbetween Slope-1 and Slope-2 but we first need to define the transition point. This is usually the Breakpoint setting, but this setting is not available in the GE 489 relay. A quick review of the manufacturer’s operate description (Figure 32) of the manual informs us that the breakpoint is pre-defined as 2 times CT. where: IOperate = operate current IRestraint = restraint current k = characteristic slope of differential element in percent (Slope 1 if IR < 2 X CT, Slope 2 if IR > = 2 X CT) IA = phase current measured at the output CT Ia = phase current measured at the neutral end CT Differential elements for phase B and phase C operate in the s ame manner. Figure 32: Percentage Differential Protection Dual Slope Characteristic Curve 26 Chapter 1: Simple Percent Dif ferential (87) Element Testing You can use the same Minimum Pickup formulas to calculate the transition from Slope-1 to Slope-2. This time we’re going to expand the formula to determine the actual W1 and W2 currents instead of operate and restraint currents. Iop > k ×Ir  IW 1  I + IW 2  − IW 2  = 0.2 ×  W1  2   0.2IW1 + 0.2 IW 2  IW 1 − IW 2  = 2 2 ×  I− = WI 1W2 +1 I W2 0.2 I W0.2 2IW 1 I−W 22 I W0.2 =1 I W2 0.2 + 2IW 1 −0.2 IW1 I W0.2 =2 I W2 2+ 1.8IW1 = 2.2 IW 2 IW 1 = 2.2IW 2 1.8 IW1 = 1.222IW 2 The maximum amount of Ir is defined as Ir<10A I + IW 2 Ir = W 1 2 9.99 = 1.222IW 2 + IW 2 2  IW 1 − IW 2   IW1 + IW 2    2   Iop 100 Ir Slope(%) =100 ×=× Slope(%) = 100 × 2 ×  IW1 − IW 2   IW 1 + IW 2  2I − 2IW 2  Slope(%) = 100 ×  W1  IW 1 + IW 2  Slope(%) ×I W+I1W=2 20 ×  IW+I1W =2 × 100W−1I 2W2 I 2 × 100 I W−12 IW2 2 200 IW 2 IW 2 = 200 IW1 − 20IW1  + 20 20IW1 +I20 W2 I W=1200I W2 200 − 20IW1 +I20 I2W1 − 200−I=W2 W 200 20IWI1W1−200 −= I W2200 I−W2 20 −180IW 1 = −220 IW 2 IW 1 = 220IW 2 180 IW 1 = 1.222IW 2 19.98 = 2.222 IW 2 The maximum amount of Ir 8.99 = IW 2 Slope 1 expected test is defined as Ir<10A Ir = currents can be defined by: IW1 = 1.222W 2 I W1 IW 2 = 1.222 9.99 = IW1 + IW 2 2 1.222IW 2 + IW 2 2 19.98 = 2.222 IW 2 8.99 = IW 2 27 The Relay Testing Handbook The new characteristic curve will look like Figure 33. Differential Protection 20/80% Characteristic Curve 50.0 45.0 40.0 t n e rr u C e t ra e p O Trip Area ) 35.0 s p 30.0 m A25.0 n i p 20.0 Io ( 15.0 Transition 2 Slope 2 Transition 1 Slope 1 10.0 5.0 Restraint Area Min 0.0 0 1 2 3 4 5 6 7 8 9 101 11 21 31 4 151 61 71 81 92 0 Restraint Current (Ir in Amps) Figure 33: Percentage Differential Protection Dual Slope Characteristic Curve 28 Chapter 1: Simple Percent Dif ferential (87) Element Testing Now we can define the expected test currents when Slope-2 is required. Iop > k ×Ir Slope(%) =100 ×=×  I + IW 2   IW 1 − IW 2  = 0.8 ×  W1  2    IW 1 − IW 2  = 2 ×  I− WI 1W2= 2IW 1 I−W 22 0.8IW1 + 0.8 IW 2 2 +1 I W2 0.8 I W0.8 I W0.8 =1 I W2 0.8 + 2IW 1 −0.8 IW1 I W0.8 =2 I W2 Slope(%) = 100 × 2.8IW 2 1.2 IW 1 = 2.333IW 2 Slope 2 expected test currents can be defined by: Slope(%) ×I W+I1W=2 × 100W−1I 2W2 I 2 80 ×  IW+I1W=2 × 100 I W−1I2W2 2 200 IW 2 80IW1  + 80 IW 2 = 200 IW1 − 80IW1 +I80 W2 I W=1200I W2 200 − 80IW1 +I80 I2W1 − 200−I=W2 W 200 80IWI1W1−200 −= I W2200 I−W2 80 −120IW 1 = −280 IW 2 IW 1 = IW1 2.333  IW 1 + IW 2  2I − 2IW 2  Slope(%) = 100 ×  W1  IW 1 + IW 2  IW 1 = 2.333IW 2 IW 2 = 2 ×  IW1 − IW 2  2+ 1.2IW1 = 2.8 IW 2 IW 1 =  IW 1 − IW 2   IW1 + IW 2    2   Iop 100 Ir 280I W2 120 IW 1 = 2.333IW 2 29 The Relay Testing Handbook The actual characteristic curve of this 87-Element using Winding-1 and Winding-2 currents can be plotted where W2 (Restraint Current) is a group of arbitrary numbers and W1 (Operate Current) uses the following formulas: • • • • W2 < 8.99AIop and< IIf ( W2 < 8.99AIop and IIf ( W2 > 10.0A)I then W I 1 = 2.333 IIf ( 0.5A) I+= then I W 1 0.5 W2 > 0.5A) I then I W 1 = 1.222 W2 W2 The spreadsheet calculation for these equations could be: I IF I= < ( W1 IFI 8.99, W2 ((I W2 *1 < .222)+ II W2 W2W2 0.5,0I.5 , *1 .222), *2 .333) W 2 Differential Protection Characteristic Curve 40 35 Trip Area Slope 2 30 t n e rr u C ) 25 s p m20 A in te ra 1W15 e I p ( O 10 Restraint Area Slope 1 5 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 Restraint Current W2 (I in Amps) Figure 34: Percentage Differential Protection Dual Slope Characteristic Curve in Amps You could use this graph to determine the expected pickup current for a Slope-1 test by choosing a W2 current greater than the Minimum Pickup and less than Slope-2. Find that current on the x-axis, follow the current up until it crosses the line, then follow the crossover point back to the other axis to determine the expected pickup. For example, we could test Slope-1 by applying 5.0A to both windings and increase the W1 curr ent until the relay operates. The relay should operate at approximately 6.0A as shown in Figure 35. Test Slope-2 by choosing a current below the Slope-2 portion of the graph (12.0A for example), follow 12.0A from the x-axis to the characteristic curve, and follow it to the y-axis. The expected pickup current for the Slope-2 test is 28A as per Figure 35. 30 Chapter 1: Simple Percent Dif ferential (87) Element Testing Differential Protection Characteristic Curve 40 35 Trip Area Slope 2 30 t n e rr u C e t a r e p O ) 25 s p m 20 A n i 1 15 I(W 10 Restraint Area Slope 1 5 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 Restraint CurrentW2 (I in Amps) Figure 35: Using Graphs to Determine Pickup Settings It can be more convenient (and accurate) to use the formulas to determine the expected pickup current as shown below. SLOPE 1 SLOPE 2 IW 1 = 1.222 IW 2 IW 1 = 2.333IW 2 IW 1 = 1.222(5.0A) IW 1 = 2.333(12.0A) IW 1 = 6.11A IW 1 = 27.996A Follow these steps to test the Differential Slope settings: 1. Determine how you will monitor pickup and set the relay accordingly, if required. (Pickup indication by LED, output contact, front panel display, etc…See previous packages of The Relay Testing Handbookfor details.) 2. Determine the Slope-1 restraint current by selecting a value between the Minimum- Pickup and Slope-2 transition points. Apply the restraint current through W2. The pickup indication should be ON because we have applied a 200% slope as per the calculations earlier in this chapter. The W2 current for our example will be 5.0A. 31 The Relay Testing Handbook 3. Apply identical current 180º from W2 into W1. The pickup indication should turn OFF because there is no operate current as the two applied currents cancel each other out. 4. Raise the W1 current until the element operates. This is the Slope-1 pickup. The measured pickup for our example is 6.175A. 5. Some organizations want more than one test point to determine slope. Repeat steps 2-4 with another restraint current between the Minimum-Pickup and Slope-2 transition points until the required number of tests are completed. 6. Test Slope-2 by repeating steps 2-4 with a restraint current greater than the Slope-1 to Slope-2 transition level. Remember that any test current greater than 10A can potentially damage the relay and should only be applied for the minimum time possible. You can switch to the pulse method to reduce the possibility of equipment damage. (Review the Instantaneous Overcurrent (50-Element) pickup procedure in previous packages of The Relay Testing Handbookfor details.) 7. Compare the pickup test result to the manufacturer’s specifications and calculate the percent error as shown in the following example. Slope-1 In our example, we calculated that the 87-Element should operate when W1 = 6.11A using the Slope-1 formula when W2 = 5.0A. We measured the pickup to be 6.175A. Looking at the “OUTPUT AND NEUTRAL END CURRENT INPUTS” specification in Figure 36, we see that the acceptable metering error is 0.05A per applied current or 0.10A including all applied currents (“Accuracy: @ < 2 x CT: ± 0.5% of 2 x CT” = 0.5% × 10 A = 0.05 A ). The difference between the test result and calculated pickup is 0.065A ( 6.175A − 6.11A = 0.065A ) and the relay passes the test based on this criteria. OUTPUT AND NEUTRAL END CURRENT INPUTS Accuracy: @ < 2 x CT: ± 0.5% of 2 x CT @ > 2 x CT: ± 1% of 20 x CT OUTPUT RELAYS Operate Time: 10ms PHASE DIFFERENTIAL Pickup Accuracy: as per Phase Current Inputs Timing Accuracy: +50ms @ 50/60 Hz or ± 0.5 % of total time Figure 36: GE Power Management 489 Specifications 32 Chapter 1: Simple Percent Dif ferential (87) Element Testing We can also calculate the manufacturer’s allowable percent error. Use “Accuracy: @ < 2 x CT: ± 0.5% of 2 x CT” from the specifications in Figure 36 because the applied cur rent is less than 2x CT (20A), the allowable percent error is 1.6%. Maximum Accuracy Tolerance × 100 = Allowable Percent Error Setting 2 × 0.5% ×(2 ×CT)  × 100 = Allowable Percent Error 6.11A 2 × 0.005 ×(2 ×5A)  6.11A × 100 = Allowable Percent Error 2 × 0.005 ×10A × 100 = Allowable Percent Error 6.11A 0.10A × 100 = Allowable Percent Error 6.11A 1.6% Allowable Percent Error The measured percent error can be calculated using the percent error formula below. Actual Value - Expected Value × 100 = Percent Error Expected Value 6.175A - 6.11A × 100 = Percent Error 6.11 A 1.06% Error Slope-2 In our example, we calculated that the 87-Element should operate when W1 = 27.996A using the Slope-2 formula when W2 = 12.0A. We measured the pickup to be 28.712A. Looking at the “Output And Neutral End Current Inputs” specification in Figure 36, we see that the acceptable metering error is 1.00A per applied current or 2.00A including all applied currents (“Accuracy: @ > 2 x CT: ± 1.0% of 20x CT”=1% x 20 x 5A= 1.00A).The difference between the test result and calculated pickup is 0.716A 28.712A ( − 27.996A = 0.716A ) and the relay passes the test based on this criteria. 33 The Relay Testing Handbook We can also calculate the manufacturer’s allowable percent error. Use “Accuracy: @ 2 x CT: ± 1.0% of 20 x CT” from the specifications in Figure 36 because the applied current is greater than 2 x CT (20A), the allowable percent error is 7.1%. Maximum Accuracy Tolerance × 100 = Allowable Percent Error Setting 2 × 1.0% ×(20 ×CT)  × 100 = Allowable Percent Error 27.996A 2 × 0.01 ×(20 ×5A)  27.996A × 100 = Allowable Percent Error 7.1% Allowable Percent Error The measured percent error can be calculated using the percent error formula below. Actual Value - Expected Value × 100 = Percent Error Expected Value 28.712A - 27.996A × 100 = Percent Error 27.996 A 2.56% Error Rule of Thumb Remember that there are other factors that will affect the test result such as: • • • Relay close time: The longer it takes the contact to close the higher the test result will be if ramping the pickup current. Test-set analog output error. Test-set sensing time. Some of these error factors can be significant and a rule-of-thumb 5% error is usually applied to test results. 8. Repeat the pickup test for all phase currents that are part of the differential scheme. If more than two windings are used, change all connections and references to W2 to the next winding under test (W2 becomes W3 of r W1-W3 tests). 34 Chapter 1: Simple Percent Dif ferential (87) Element Testing SLOPE 1 TESTS (Amps) RESTRAINT TEST W1 5 A W2 W1 8 A W2 W1 NA APH A S E(A ) BPH A S E( A ) 6.175 9.896 NA W3 CP H A S E( A ) 6.175 9.899 NA M FG( A ) % ERROR 6.110 6.175 9.902 NA 1.06 9.776 1.06 1.23 1. 0 6 1.26 1.29 NA SLOPE 2 TESTS (Amps) RESTRAINT TEST W1 1 2A W2 W1 1 5A W2 W1 NA A PHASE (A) B PHASE (A) 28.712 36.082 NA W3 C PHASE (A) 28.712 36.083 NA MFG (A) 28.712 36.085 NA % ERROR 27.996 2.56 2.56 34.995 3.11 2.56 3.11 3.11 NA Alternate Slope Calculation There is another way to test slope that does not require as much preparation. Follow the same steps as the previous test and test 2 points on each slope and record the results. Determine slope using the rise-over-run graphical method as shown in Figure 37 and the following formulas. Remember to use the OPERATE I ( IW1 − IW 2 ) and IRESTRAINT ( IW1 + IW 2 ) formulas. 2 Differential Protection Characteristic Curve 40 35 Trip Area Slope 2 Rise2 30 t n e rr u C e t ra e p O Run2 ) 25 s p m A 20 n i 1 W (I 15 10 Slope 1 Rise1 5 Restraint Area Run1 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 Res traint Current (IW2 in Amps) Figure 37: Determine Slope by Rise/Run Calculation 35 The Relay Testing Handbook %Slope1 = 100 × %Slope1 = 100 × %Slope1 = 100 × %Slope1 = 100 × %Slope2 = 100 × Rise Run %Slope2 = 100 × IOPERATE 2 − IOPERATE 1 IRESTRAINT 2 − IRESTRAINT1 %Slope2 = 100 × (IW2 I − 2)I W(1 −I W 12 1) − 1 W2  IW 12IW+22  I W1 I1W2 1 + −    2 2   (9.90A − 8A) − (6.175A − 5A)  9.90A +8A  6.175A+5A   −  2 2     %Slope1 = 100 × %Slope2 = 100 × %Slope1 = 100 × IOPERATE 2 − IOPERATE 1 IRESTRAINT 2 − IRESTRAINT1 (IW2 −2 2)I W(1 −I W 12 1) − 1 IW  IW12IW+22 I W1 I1W2 1 + −    2  2   (36.08A − 15A) − (28.71A − 12A)  36.08A + 15A  28.7 1A+12A   −  2 2     %Slope2 = 100 × 1.896A − 1.175A 8.948A − 5.5875A 21.082A − 16.712A 25.541A − 20.356A %Slope2 = 100 × 0.721 3.3605 Rise Run 4.37 5.185 %Slope2 = 100 × 0.843 Slope1 = 21.5% Slope2 = 84.3% SLOPE 1 TESTS (Amps) RESTRAINT TEST A PHASE (A) W1 5.0 W2 6.175 W1 8.0 W2 9.896 W1 NA W3 NA B PHASE (A) C PHASE (A) 6.175 SLOPE (%) % ERROR 6.175 9.899 9.902 NA 21.5 21.5 21.6 7.28 7.67 8.07 NA SLOPE 2 TESTS (Amps) RESTRAINT TEST A PHASE (A) W1 12.0 W28.712 2 W1 15.0 W2 W1 NA W3 36 B PHASE (A) C P HASE (A) SLOPE (%) % ERROR 28.712 28.712 36.082 NA 36.083 NA 36.085 NA 84.3 84.3 84.3 5.35 5.37 5.39 Chapter 1: Simple Percent Dif ferential (87) Element Testing 6. Tips and Tricks to Overcome Common Obstacles The following tips or tricks may help you overcome the most common obstacles. ¾ ¾ ¾ ¾ ¾ ¾ Before you start, apply current at a lower value and review the relay’s measured values to make sure your test-set is actually producing an output and your connections are correct. 180º apart? If the pickup tests are off by a 3 , 1.5, or 0.577 multiple; the relay probably is applying correction factors and the test procedures in the next chapter should be used. Are you applying the currents into the same phase relationships? Did you calculate the correct Tap? Don’t forget to use the entire operate and restrained calculations. 37 Chapter 2 Percent Differential (87) Element Testing The previous chapter discussed differential protection on a single-phase basis, which is fine when discussing the simplest differential protective elements typically used for generator or motor protection. There are several new problems to be resolved when differential protection is applied to transformers which add complexity to our testing procedure: ¾ ¾ ¾ ¾ The simple definition of differential protection (current in equals current out) no longer applies (now power in equals power out) because the primary and secondary sides of the transformer have different voltage levels. Different voltage levels create different CT ratios and we now have to compensate for different Tap values on either side of the protected system. The situation becomes more complex with Delta-Wye or Wye-Delta transformers. The phase-angle on the primary and secondaries of the transformer are no longer 180 degrees apart. Electro-mechanical relays solved this Wye-connected problem by changing thethe CTphase connections compensateby forrelay the phase shift, but most digital relays use CTs and shift is to compensated settings. Transformer differential relays are designed to ignore the large inrush current that occur when a transformer is initially energized. The relay should trip if we close into a fault. Additional protection is applied to operate quickly to clear the fault. 39 The Relay Testing Handbook 1. Application We will start with a description of zones of protection typically used in protection schemes. A) Zones of Protection Zones of protection aredefined by strategic CT placement in an electrical system and there are often overlapping zones to provide maximum redundancy. The differential protection should operate when a fault occurs inside the zone and ignore faults outside the zone. The following figure depicts a typical electrical system with multiple zones of protection. GCB-1 GCB-2 CT1 CT2 CT3 87T1 GSU XFMR T1 87OA CT8 CT4 CT5 AUX CT9 87T2 XFMR T2 87G G G1 CT10 CT6 CT7 GEN CT11 Figure 38: Zones of Protection Example There are four differential relays in Figure 38 that protect each major piece of equipment and the overall plant. Relay 87OA is an overall differential relay with 4 inputs that will operate for any fault within the plant as defined by the locations of its input CTs; CT1, CT2, CT7, and CT11. • 40 Chapter 2: Percent Dif ferential (87) Element Testing • • GSU XFMR T1 is protected by differential relay 87T1 that will operate if a fault is detected between CT3, CT5, and CT8. 87T2 protects AUX XFMR T2 between CT4 and CT6. The overlap between CT4 and CT5 provides 100% protection between the two transformers. Conversely, the gap between CT8 and CT9 means that a fault in that gap will only trip the 87OA relay and will be difficult to locate. B) Tap i) Simple Differential Protection The previous chapter demonstrated differential protection on a single-phase basis which should be applied to all three phases as shown in Figure 39. This is the same protection but displayed on a 3 phase basis. Because there is no voltage difference or phase shift between windings, we were able to isolate one phase at a time to perform our testing. The CT ratios on both sides were identical and we could ignore the Tap setting as well. 100 A A Phase 100:5 CT 100:5 CT IA a Phase Ia B Phase b Phase IB Ib C Phase IC c Phase G Ic Iop1 IrA Ira IrB Irb IrC Irc Iop2 Iop3 Figure 39: 3 Phase Generator Differential Protection 41 The Relay Testing Handbook Tap settings are very important when more complicated differential schemes are applied such as the 115,000V to 34,500V; 30 MVA transformer depicted in Figure 40. 151 A A Phase 200:5CT1A XFMR 1 30MVA 115kV:34.5kV Y:Y 600:5CT1a a Phase Ia=4.19A@180º IA=3.78A@0º B Phase 200:5 CT1B 600:5 CT1b b Phase IB=3.78A@-120º C Phase 503 A Ib=4.19A@60º 200:5 CT1C 600:5 CT1c IC=3.78A@120º c Phase Ic=4.19A@-60º IA=3.78A@0º IrA Iop1 =0.4A Ira Ia=4.19A@180º Ir1=3.98A IB=3.78A@-120º IrB Iop2 =0.4A Irb Ib=4.19A@60º Ir2=3.98A IC=3.78A@120º IrC Iop3 =0.4A Irc Ic=4.19A@-60º Ir3=3.98A Figure 40: 3 Phase Transformer Differential Protection A quick review of Figure 40 (that does not apply Tap settings) shows that the Iop current under normal conditions in each phase is 0.4 A. If we apply the percent-slope formula from the previous chapter, we discover that there is approximately a 10% slope under normal operating conditions. %Slope =100 × I 0.4 =OP × 100 = 10.05% IRestraint 3.98 Remember that these are ideal conditions and there is an additional 10% allowable CT error under symmetrical conditions and 20% error under asymmetrical conditions. We can apply Winding Taps to compensate for the different nominal currents. 42 Chapter 2: Percent Dif ferential (87) Element Testing Figure 41 displays the same protection with a 3.80A Tap setting on Winding-1 and 4.2A on Winding-2. Different Tap settings are applied, so it is now easier to use % of Tap or per-unit for all of our differential calculations. XFMR 1 30MVA 115kV:34.5kV Y:Y 151 A A Phase 200:5CTA 200:5 CTB 600:5 CTc IC=3.78A@120º = Actual Tap = b Phase Ib=4.19A@60º 200:5 CTC %Tap a Phase 600:5 CTb IB=3.78A@-120º C Phase 600:5CTa Ia=4.19A@180º IA=3.78A@0º B Phase 503 A c Phase Ic=4.19A@-60º 3.78A 0.99 3.8A = IrA=0.99@0º IrA Iop1 =0.01 Ira %Tap = Actual Tap = 4.19A 1.00 4.2A = Ira=1.00@180º Ir1=1.00 IrB=0.99@-120º IrB Iop2 =0.01 Irb Irb=1.00@60º Ir2=1.00 IrC=0.99@120º IrC Iop3 =0.01 Irc Irc=1.00@-60º Ir3=1.00 Figure 41: 3 Phase Transformer Differential Protection Using Tap Settings Now the measured slope is less than 1% under normal conditions in an ideal situation. %Slope =100 × I 0.01 =OP × =100 0.01% IRestraint 1.00 Notice that all of the numbers in the slope calculation do not include A oramps because these numbers are now related in percent of Tap or per-unit (PU). Understanding the Tap settings and correctly applying them to your differential calculations is vital when testing more complicated differential protection. 43 The Relay Testing Handbook ii) Transformer Differential Protection with E-M Relays Unfortunately, most transformers do not have Wye-Wye connections and many have Delta-Wye or Wye-Delta Connections. The Wye-Delta transformer in Figure 42 has essentially the same characteristics (Voltage, MVA, etc) but the transformer secondary has been reconfigured for a delta connection which completely changes the differential protection scheme. We will go through all of the changes in Figure 42 on a step-bystep basis to help you understand all of the challenges and it does get quite involved. Remember that we will discuss much simpler methods that require less analysis later in the chapter. XFMR 1 30MVA 115kV:34.5kV Y: 151 A H1 200:5CTH1 Ih1=3.78A@0º H2 º 0 1 º 0 3 @ A 5 5 . 6 = 3 h -I 1 h I 2 @ A 5 5 . 6 = 1 h -I 2 h I 9 @ A 5 5 . 6 = 2 h -I 3 h I Aº 1 Ia 9 0 2 @ @1 2 5 I 4 1 B 0 A º A 1 b I 9 2 º 0 4 2 @ @1 1 5 I 2 1 C 0 A º º A0 2 Ic 1 9 1 2 @ X1 600:5 CTX2 200:5 CTH3 Ih3=3.78A@120º º 0 3 600:5CTX1 @1 5 0 1 IA º A 200:5 CTH2 Ih2=3.78A@240º H3 503 A X2 600:5 CTX3 º 0 7 2 A @ 9 1 . 4 = b IIc = 3 x I H0 Iop1 =0.01 IrA=0.99@330º IrA Ira X3 Ira=1.00@150º º 0 3 @ A 9 1 . 4 = a IIb = 2 x I º 0 5 1 A @ 9 1 . 4 = c IIa = 1 x I Ir1=1.00 Iop2 =0.01 IrB=0.99@210º IrB Irb Irb=1.00@30º Ir2=1.00 %Tap = Actual Tap = 6.55A 0.99 6.60A = IrC=0.99@90º IrC Iop3 =0.01 Irc %Tap = Actual Tap = 4.19A 1.00 4.2A = Irc=1.00@270º Ir3=1.00 Figure 42: Wye-Delta Transformer Differential Protection Using CT Connections Let’s start with the primary connections. The High and Low side currents (and corresponding CT ratios) entering and leaving the transformer have not changed 44 Chapter 2: Percent Dif ferential (87) Element Testing because the MVA and voltage ratings haven’t changed. However, we had to relabelmany of the measured currents because of the new connections. The current entering H1, H2, and H3 is now labeled with the capital H designation to indicate cur rent measured at the primary bushings. The H-windingis connected in Wye and the primary winding currents equal the terminal current. (CTH1 = IA, CTH2 = IB, CTH3= IC). The CT secondary currents have been relabeled with a lower case Ih1, Ih2, and Ih3 to indicate that they are the secondary currents of the bushing CTs. These CTs have been connected in Delta to compensate for the Delta-Wye shift of the transformer. The current entering the differential relay’s transformer primary restraint coils is labeled IrA, IrB, and IrC and is NOT the CT secondary current. The restraint current is the resultant of the delta connection. If you follow the circuit back from IrA,uyo will discover that IrA is connected to the polarityof Ih1 and the non-polarity of Ih3. IrB isconnected to the polarity of Ih2 and the non-polarity of Ih1. IrC is connected to the polarity of Ih3 and the non-polarity of Ih2. We must add these currents together vectorially to determine the restraint currents. Add the currents connected to the polarity marks to the currents connected to the non-polarity marks rotated by 180º as shown below. Remember, if you add two vectors that have equal magnitudes and are 60º apart, you can determine the resultant vector by multiplying the magnitude by √3 and split the difference in angles Ih3 = 3.78 Amp Ih1 + −Ih3 3.78@0−+° (3.78@ ° 120 ) 0 12 90 60 3 0 0 5 3.78@0+° (3.78@1 +° °20 180 ) 3.78@0 ° + 3.78@30 0 ° 180 2 1 0 1 0 24 0 270 0 30 3 3 0 Ih1 = 3.78Amp 6.55@330 ° 0 12 Ih2 + −Ih1 3.78@2 40+°− (3.78@0 ° ) +° ° 180 ) 3.78@24 0+° (3.78@0 3.78@24 0° + 3.78@1 80 ° 6.55@210 ° 1 24 0 3.78@1 20+° (3.78@24 +°° 0 180 ) 3 0 0 12 1 270 90 0 30 0 Ih1 = 3.78Amp 3 0 0 0 12 1 3 3 60 0 5 180 2 1 0 Ih3 + −Ih2 (3.78@24 ° 0) 60 0 24 0 3.78@1 20−+° 90 0 5 180 2 1 0 270 90 0 30 3 3 0 Ih1 = 3.78Amp -Ih2 = 3.78 Amp 60 3 0 0 5 180 2 1 0 0 24 0 270 0 30 3 3 0 3.78@1 20° + 3.78@42 0 ° 3.78@1 20+° 3.78@60 ° −°(°420 360 ) IrA = 6.55 Amp 6.55@90 ° 45 The Relay Testing Handbook The primary winding Tap setting must change because the measured current at the relay is √3 larger due to the delta-connected CTs. The new Tap for the primar y winding is 6.6A. The transformer secondary winding is connected in Delta and, therefore, the CTs are connected in Wye to compensate for the phase shift between the primary and secondary windings. The transformer ratio is the same as the Wye-Wye example which means that the current magnitude flowing through the X-Bushings have not changed. The phaseangles and winding currents will change due to the Delta connection. The Ia current magnitude can be calculated one of two ways. We can use logic and the Delta-Wye rule of thumb that states the current inside the delta is √3 smaller than the current leaving the delta.Ia = IX1 = 503A =290.4A . Or we can calculate the Ia, I,b, and Ic 3 3 currents using the transformer ratio. (Remember that transformer ratios are listed as phase-phase values.) Ia VAN = IA Vab Ia = IA×VAN Vab   34.5kV 151A@0° ×  VAB Ia =   34.5kV 151A@0° × 115kV Ia = Ia = 291A@0 ° 46 Ib VBN = IB Vbc Ib =   IB×VBN Vbc   34.5kV 151A@240° ×  VBC 3 Ib =   3   34.5kV 151A@240° × 115kV Ib = Ic VCN = IC Vca Ib = 291A@240 ° Ic =   IC×VCN Vca   34.5kV 151A@120° ×  VCA 3 Ic =   3   34.5kV 151A@120° × 115kV Ic = Ic = 291A@120°   3   3 Chapter 2: Percent Dif ferential (87) Element Testing XFMR 1 30MVA 115kV:34.5kV Y : 151 A H1 200:5 CTH1 Ih1=3.78A@0º H2 600:5 CTX1 @1 5 0 1 IA º A Aº 1 a I 9 0 2 @ @1 2 5 I 4 1 B 0 A º A 1 b I 9 2 º 0 4 2 @ @1 1 5 I 2 1 C 0 A º A Ic 1 9 2 º 0 2 1 @ 200:5 CTH2 Ih2=3.78A@240º H3 503 A 600:5 CTX2 200:5 CTH3 Ih3=3.78A@120º 600:5 CTX3 X1 X2 X3 H0 We can calculate the X-Bushing currents(Ia, Ib, and Ic) using the same calculations from the Delta CTs on the high side. IX1 is connected to Ia and –Ic, IX2 is connected to Ib and –Ia, and IX3 is connected to Ic and –Ib. The current is entering the non-polarity mark of the CTs andthe CT secondary current (1x) will be the primary current divided by the CT ratio and rotated by 180º. TRANSFORMERCURRENT CTOUTPUT Ix1= IX1=Ia + −Ic IX1=291@0− +° 503A@330 ° (291@120 ° ) IX1=291@0+° (291@12 +° ° 0 1X1 +180 ° CT Ratio 180 ) IX1=291@0 ° + 291@30 0 ° IX1=503@330 ° Ix1= ( 600 5) +180 ° 503A@330 ° Ix1= +180 ° 120 Ix1=4.19A@330° + 180 ° Ix1=4.19A@510° Ix1=4.19A@150° (510 −° IX2=Ib + −Ia IX2=291@24 0 °+− Ix2= (291@0 ° ) IX2=291@24 0+° (291@0 +° ° 180 ) Ix2= °360 ) 1X2 +180 ° CT Ratio 503A@210 ° +180 ° 120 IX2=291@240 ° + 291@1 80 ° Ix2=4.19A@210° + 180 ° IX2=503@210 ° Ix2=4.19A@30° IX3=Ic + −Ib IX3=291@1 20− +° Ix3= (291@24 ° 0) IX3=291@120+° (291@24 +° ° 0 180 ) Ix3= 1X3 +180 ° CT Ratio 503A@90° +180 ° 120 IX3=291@120 ° + 291@60 ° Ix3=4.19A@90° + 180 ° IX3=503@90 ° Ix2=4.19A@270° 47 The Relay Testing Handbook XFMR 1 30MVA 115kV:34.5kV Y : 503 A 600:5 CTX1 X1 Aº 1 a I 9 0 2 @ 600:5 CTX2 A 1 b I 9 2 º 0 4 2 @ A 1 Ic 9 2 º 0 2 1 @ X2 600:5 CTX3 X3 We can now calculate the restraint currents for each winding and phase and the operate current for each phase. Remember that all calculations are in percent of Tap or per-unit. IrA = IrA = Ih1 − Ih3 Tap1 6.55A@330 ° 6.60A IrA = 0.99@33 0 ° Ira = Ira = Ix1 Tap2 4.19A@150 ° 4.2A Ira = 1.00@15 0 ° Ir1 = Ir1 = IrA + Ira 2 0.99 + 1.00 2 Ir1 = 1.99 2 Ir1 = 1.00 IrB = IrB = Ih2 − Ih1 Tap1 6.55A@210 ° 6.60A IrB = 0.99@21 0 ° Irb = Irb = Ix2 Tap2 4.19A@30 ° 4.2A Irb = 1.00@30 ° Ir2 = Ir2 = IrB + Irb 2 0.99 + 1.00 2 Ir2 = 1.99 2 Ir2 = 1.00 IrC = IrC = Ih3 − Ih2 Tap1 6.55A@90 ° 6.60A IrC = 0.99@90 ° Irc = Irc = Ix3 Tap2 4.19A@270 ° 4.2A Irc = 1.00@27 0 ° Ir3 = Ir3 = IrC + Irc 2 0.99 + 1.00 2 Ir3 = 1.99 2 Ir3 = 1.00   Iop1 = IrA + Ira Iop1 = 0.99@330 + ° 1.00@150 °   Iop2 = IrB + Irb Iop2 = 0.99@210 + ° °1.00@30   Iop3 = IrC + Irc Iop3 = 0.99@90 + ° 1.00@270 ° Iop1 = 0.01 Iop2 = 0.01 Iop3 = 0.01 48 Chapter 2: Percent Dif ferential (87) Element Testing º 0 3 3 @ A 5 .5 6 = 3 h I1 h I º 0 1 2 @ A 5 .5 6 = 1 h I2 h I º 0 9 @ A 5 .5 6 = 2 h I3 h I º 0 7 2 @ A 9 .1 4 = b IIc = 3 x I Iop1 =0.01 IrA=0.99@330º IrA Ira Ira=1.00@150º º 0 3 @ A 9 1 . 4 = a IIb = 2 x I º 0 5 1 @ A 9 .1 4 = c -I a I = 1 x I Ir1=1.00 Iop2 =0.01 IrB=0.99@210º IrB Irb Irb=1.00@30º Ir2=1.00 %Tap = Actual Tap = 6.55A 0.99 6.60A = IrC=0.99@90º IrC Iop3 =0.01 Irc %Tap = Actual Tap = 4.19A 1.00 4.2A = Irc=1.00@270º Ir3=1.00 There is no reason to perform all three calculations when dealing with a balanced 3-phase condition as described previously. As you can see, all the phases have the same operate and restraint currents. Most calculations assume a balanced 3-phase condition and are usually only performed on A-phase. 49 The Relay Testing Handbook iii) Transformer Differential Protection with Digital Relays Most digital relays have correction factors and other algorithms to compensate for the phase shift between Delta-Wye transformers, and the Tap setting is relatively simple. The CTs are almost always connected in Wye and the Tap setting calculation is very similar to the simple differential protection described previously. Figure 43 displays the same transformer described in Figure 42 witha digital relay. XFMR 1 30MVA 115kV:34.5kV Y: 151 A H1 200:5CTH1 Ih1=3.78A@0º H2 600:5CTX1 @1 5 0 1 IA º A Aº 1 a I 9 0 2 @ @1 2 5 I 4 1 B 0 A º A 1 b I 9 2 º 0 4 2 @ A Ic 1 9 2 º 0 2 1 @ 200:5 CTH2 X1 Ix1=4.19A@150º 600:5 CTX2 Ih2=3.78A@240º H3 503 A 200:5 CTH3 Ix2=4.19A@30º 600:5 CTX3 @1 1 5 I 2 1 C 0 A º Ih3=3.78A@120º X2 X3 Ix3=4.19A@270º H0 %Tap = Actual Tap = 6.55A 0.99 6.60A IrA = IrA=0.99@0º Iop1 =0.01 Ira=1.00@180º W1CTC=12 %Tap = Actual Tap = 4.19A 4.2A 1.00 = Ira W2CTC=1 Iop2 =0.01 IrB IrB=0.99@240º Irb=1.00@60º W1CTC=12 Irb W2CTC=1 Iop3 =0.01 IrC W1CTC=12 IrC=0.99@120º Irc=1.00@300º Irc W2CTC=1 Figure 43: Wye-Delta Transformer Differential Protection Using CT Connections 50 Chapter 2: Percent Dif ferential (87) Element Testing Protecting this transformer with a digital relay has simplified the connections substantially. Both winding CTs are connected in Wye and are connected to the restrained coils (remember all of the coils have been replaced with digital algorithms now) and we use the same actual-current vs. Tap-current to determine the per-unit or percent-of-Tap current. The symbol represents the relay’s phase compensation settings which are “W1CTC=12” and “W2CTC=1” for this application. (Don’t worry, these settings will be explained in the next section.) The phase compensation angle replaces the different CT configurations required by electromechanical relays. The end result is the same with operate currents of 0.01A. C) Phase-Angle Compensation Modern relays use formulas to compensate for the phase shifts between windings on transformers and can even compensate for unwanted zero-sequence currents. All CTs are typically Wye-connected and the relay’s settings are changed to match the application. Unfortunately there is no standard between relays or relay manufacturers and most problems in transformer differential applications occur trying to apply the correct compensation settings. All phase-angle compensation settings are based on the transformer windings and their phase relationship using different codes depending on the manufacturer or relay model. The winding is always designated with a “D” or “d” for Delta-connected windings; and “Y” or “y” for Wye-connected windings. The third designation is the phase shift between windings and can be designated by a connection description, phase-angle, or clock position. Beckwith Electric and older SEL relays use the connection description as shown in the following figures: H1 Y : Y X1 A a PHASE ANGLE COMPENSATION H2 X2 B b H3 • X3 C • c • H0 “Y” is the primary designation for the Wyeconnected winding. “Y” is the secondary designation for the Wyeconnected winding. This is a "YY" transformer. X0 51 The Relay Testing Handbook : H1 PHASE ANGLE COMPENSATION X1 A a H2 X2 B b • • • H3 X3 C c • “D” is the primary designation for the Deltaconnected winding. “D” is the secondary designation for the Deltaconnected winding. Both windings are “AC” because the H1 and X1 bushing is connected to A and C phases. This is a "DACDAC" transformer. PHASE ANGLE COMPENSATION IF H IS WINDING 1 H1 Y : • X1 A a • • H2 X2 B b H3 PHASE=ANGLE COMPENSATION IF X IS W1 X3 C • “Y” is the W1 designation. “D” is the W2 designation. “AC” is the third designation because the X1 bushing is connected to a and C-Phases. This is a "YDAC" transformer. c • • H0 • • “D” is the W1 designation. “AC” is the second designation because the W1 winding is Delta and the X1 bushing is connected to A and C phases. “Y” is the W2 designation. This is a "DACY" transformer. PHASE ANGLE COMPENSATION IF H IS WINDING 1 • H1 Y : X1 A a • • H2 X2 B b • “Y” is the W1 designation. “D” is the W2 designation. “AB” is the third designation because the X1 bushing is connected to a and b phases. This is a "YDAB" transformer. PHASE ANGLE COMPENSATION IF X IS WINDING 1 H3 X3 C c • • H0 • • 52 “D” is the W1 designation. “AB” is the second designation because the W1 winding is Delta and the X1 bushing is connected to a and b phases. “Y” is the W2 designation. This is a "DABY" transformer. Chapter 2: Percent Dif ferential (87) Element Testing Some transformer differential relays define the phase relationship between windings in their settings using the actual phase displacement or clock positions asa simple reference. 0º is shifted to a vertical line to make the clock reference work, and Figures 44 and 45 display the phase-angle/clock references. It is extremely important to understand what reference the relay uses for phase-angles. Some relays, such as SEL, use a leading phaseangle reference as shown in Figure 44 wherethe angles increase in the counter-clockwise direction. Other relays, such as GE Multilin, use a lagging reference and the angles increase in the clockwise direction. k loc o'c 11 11 º 30 0 1 ck o cl o' 10 º 0 6 12 o'clock 0 or 12 0º k loc o'c 11 11 º 0 33 1o 'clo 33 0º 1 ck or -30 º 3 0 0 º 2 o 'c l o 2 oc r k -6 0 º 9 o'clock 9 90º 3 o'clock 3 270º or -90º 8 o 1 8 'clo 2 ck 0 º 4 7o 'clo ck 15 7 0º ck 'clo º 5 o 5 150 º ck 0 2 lo 'c -1 o 4 r o º 0 4 2 6 o'clock or 6 0º 21 180º or -180º Figure 44: Phase Relationship / Clock Position with Leading Angles 0 1 12 o'clock 0 or 12 0º 1o 'clo 1 ck 30 º k c lo 'c o 10 2 o 'c 6 2 lo 0 ck º º 0 0 3 9 o'clock 9 270º 3 o'clock 3 90º 8 o ' 2 8 clo 4 ck 0 º 4 7o 'clo ck 21 7 0º 6 o'clock 6 180º ck lo 'c o 4 0º 2 1 ck 'clo 5o 5 0º 15 Figure 45: Phase Relationship / Clock Position with Lagging Angles Many people assume that the high voltage winding is the primary winding but this is not true. The primary winding could be the winding that is first energized [e.g. the grid (high voltage) side of a generator step-up transformer], the winding that is connected to the primary source [e.g. the generator (low voltage) side of a generator set-up transformer], or arbitrarily chosen by the design engineer. The primary winding in transformer differential protection is determined by the CT connections to the relay. The CT’s connected to the following terminals in the most common relays are considered to be the primary windings to the relay: • • • • • GE/Multilin SR-745—Terminals H1, H2, H3, G1, G2, G3 GE T-60—f1a, f2a, f3a, f1b, f2b, f3b Beckwith Electric Co. Inc. M-3310—51, 49, 47, 50, 48, 46 Schweitzer Engineering Laboratories SEL-587—101, 103, 105, 102,104, 106 Schweitzer Engineering Laboratories SEL-387—Z01, Z03, Z05, Z02, Z04, Z06 There is an easy and hard way to determine transformer compensation settings that can be gleaned from the transformernameplate or the single and three linedrawings. I always recommend looking at the nameplate instead of drawings to ensure you have the most accurate information. 53 The Relay Testing Handbook 1) The Hard Way The hard way requires a three line drawing of the transformers and a little vector addition. We’ll review the 6 most common transformer connections and determinethe vector relationship between windings. The first example is a Wye-Wye transformer with Wye-connected CTs as shown in the following example. CT1 400:5 H1 PHA IH1=IA@0º CT2 IA @ 0 º º 0 @ a I H2 IH2@-120º H3 PHC IH3@120º IB @ 1 2 0 º º 0 2 1 @ b I IC @ 1 2 0 º º 0 2 1 @ Ic H0 1A G1 1200:5 IX1=Ia@0º X2 PHB H1 X1 H2 1B G2 IX2@-120º X3 IX3@120º X0 H3 H4 1C 2A G3 G4 H5 2B G5 H6 2C G6 GE/MULTILIN-745 Figure 46: Wye-Wye Transformer You should always start with the Wye-connected winding when determining phase relationships and the primary winding current phasors are plotted in the first vector diagram. Follow the current flowing through the H1terminal into the IA winding. The currents are the same and all three-phase primary currents are plotted in the first phasor diagram of Figure 47. 54 Chapter 2: Percent Dif ferential (87) Element Testing As you follow the current through the transformer’s AØ primary winding, an opposite current flows out the aØ secondary winding and flows through the X1 bushing. The current flowing into the H1 bushing has the same phase relationship as the current flowing through the X1 Bushing. The secondary current is plotted in the second phasor diagram 180º from the actual current flowing into the relay to make the relationship between windings easier to understand. Only the H1 and X1 currents are used when determining the vector relationships and are plotted in the third phasor diagram. Using this information, we can determine the transformer vector relationship is Y0y0; “Y” for the primary winding connection, “y” for the secondary connection, and “0” to show that both windings are at the 0 o’clock position. We usually drop the first 0 and the correct notation would be "Yy0". It is important to note that if the phasor diagrams were displayed on the actual relay software, 1 o'clock would be 30º and not -30º as shown because this relay uses the phase relationship in Figure 45. All examples in this book use the Figure 44 characteristic to better illustrate the difference between connections. k loc o'c 11 11 ° 30 1 ck lo 'c o 0 ° 0 1 60 12 o'clock 0 or 12 0° IA=IH1 k loc o'c 11 11 ° 30 1o 'cl oc 33 k 0° 1 or -3 0° -6 0 ° 2 o 'c l o 2 oc r k 3 0 0 ° 9 o'clock 9 90° 3 o'clock 3 -90° or 270° I 8 1 1 2 8 0 ° o 'c lo ck C= IH 3 IB =I 6 o'clock 6 180° k oc 'cl ° 5 o 5 210 r °o 50 -1 o ck lo 'c 4 -1 0 2 o ° r 2 ° 0 4 k loc o'c 11 11 ° 30 1o 'cl oc 33 k 0° 1 or -3 0° -6 0 Ia=IX1 2 ° 8 o ' 1 8 cl o 2 ck 0 ° o cl o 'c 0 1 o 2 loc r k 3 0 0 ° 9 o'clock 9 90° 2 H 4 7o 'cl o 7 ck 15 0° ck lo 'c o 0 ° 0 1 60 12 o'clock 0 or 12 0° 3 o'clock 3 -90° or 270° Ic = I X3 IX I b= 6 o'clock 6 180° IH1=Y0 1o 'cl oc 33 k 0° 1 or -3 0° -6 ' o 10 ° 0 6 0 ° IX1=y0 2 o 'c o 2 loc r k 3 0 0 ° 9 o'clock 9 90° 3 o'clock 3 -90° or 270° 2 4 7o 'cl o 7 ck 15 0° ck 12 o'clock 0 or 12 0° k oc 'cl ° 5 o 5 210 r °o 50 -1 o ck lo 'c 4 0 2 -1 ° o r 2 0 4 ° 8 o ' 1 8 clo 2 ck 0 ° Y0y0 = Yy0 4 7o 'cl o 7 ck 15 0° 6 o'clock 6 180° k oc 'cl ° 5 o 5 210 r °o 50 -1 o ck lo 'c 4 2 -1 ° 0 o r 4 2 ° 0 Figure 47: Wye-Wye Transformer Phasor Diagram 55 The Relay Testing Handbook Our next example uses a Delta-Delta transformer. There is no Wye-connected winding in this transformer configuration and we will start with the primary winding as defined by the CTs connected to F1a, F2a, F3a, F1b, F2b, and F3b. CT1 CT2 400:5 H1 IH1=IA-IC@-30º PHA 1200:5 IA @ 0 º º 0 @ a I IB @ -1 2 0 º º 0 2 1 @ b I IC @ 1 2 0 º º 0 2 1 @ c I H2 IH2@-150º H3 PHC IH3@90º 1A F1b IX1=Ia-Ic@-30º X2 PHB F1a X1 F2a 1B F2b IX2@-150º X3 IX3@90º F3a M1a M2a 2A 2B 2C M1b M2b M3b 1C F3b M3a GENERAL ELECTRIC T-60 Figure 48: Delta-Delta Transformer Connections The current flowing throughofH1 thewinding transformer “IA non-polarity and -IC” currents H1 is connected to the polarity theisAØ and the of thebecause CØ winding. The first phasor diagram demonstrates the IA and -IC addition and the final result “IH1” is found at the 1 o’clock position or -30º. The current flowing through X1 is “Ia and -Ic” because X1 is connected to the polarity of the aØ winding and the non-polarity of the cØ winding. The secondary current is plotted in the second phasor diagram 180º from the actual current flowing into the relay to make the relationship between windings easier to understand. The second phasor diagram demonstrates the Ia and -Ic addition and the final result “IX1” isound f at the 1 o’clock position or -30º. 56 Chapter 2: Percent Dif ferential (87) Element Testing Only the H1 and X1 currents are used when determining the vector relationships and are plotted in the third phasor diagram. Using this information, we can determine the transformer vector relationship is D1d1; “D” for the primary winding connection, “d” for the secondary connection, and “1” to show that both windings are at the 1 o’clock position. It is important to note that if the phasor diagrams were displayed on the actual relay software, 1 o'clock would be 30º and not -30º as shown because this relay uses the phase relationship in Figure 45. All examples in this book use the Figure 44 characteristic to better illustrate the difference between connections. The primary winding should always be at the 0 or 12 o’clock position and we can rotate both phasors as shown in the fourth phasor diagram to display a “D0d0” transformer. The first “0” is usually dropped from the designation and the Delta-Delta connection is displayed as “Dd0.” You could also change the reference instead of the phasors as shown in the fifth phasor diagram. k loc o'c 11 11 ° 30 lo 0 1 12 o'clock 0 or 12 0° k c 'c o 10 ° 0 6 k loc o'c 11 11 ° 30 1o 'cl o 1 ck °o r- 33 0 30 IH ° 1= IA -IC -6 0 ° IA -IC 9 o'clock 9 90° o 'c o 2 loc r k 3 0 0 ° I H 3 8 2 8 0 ° o 'c 1 'c o 10 ° 0 6 lo c k 4 ock 'cl ° 5o 5 10 r2 °o 50 -1 6 o'clock 6 180° o k c lo 'c 4 - 2 1 ° 0 o r 4 2 0 k c lo 'c o 10 ° 0 6 33 IH1=D1 IX 1 ° 2 o 'c o 2 loc r k 3 0 0 ° ock 'cl ° 5o 5 10 r2 °o 50 -1 9 4 k oc 'cl ° 5 o 5 210 r °o 50 -1 o 'c lo c k 4 0 2 -1 ° o r 2 6 ° 0 0 4 -6 0 2 ° o 'c o 2 loc r k 3 0 0 ° 9 o'clock 9 90° 3 o'clock 3 -90° or 270° o k c lo 'c 4 - 1 0 2 o ° r 2 ° 0 4 o 'c lo c 0 9 4 7o 'cl o 7 ck 15 0° 11 o'clock 11 30° k 9 D1d1 8 o ' 1 8 clo 2 c 0 k ° IH 1= D1 ° -3 0 ° - 0 2 1 ° o r 2 0 4 ° 2 o'clock 2 -60° or 300° 7 1 ock 'cl ° 5o 5 10 r2 °o 50 -1 k c lo 'c 4 1 o 'c o 1 loc r k 3 3 0 ° 8 o'clock 8 120° ° 6 o'clock 6 180° o 12 o 0 o 'clo ck r 0° 12 IX 1= d1 3 o'clock 3 -90° or 270° D1d1 = Dd0 0 1o 'cl oc 33 k 0° 1 or -3 0° IH 1= D1 IX 1= d1 k loc o'c 10 10 ° 60 -6 0 6 o'clock 6 180° 6 o'clock 6 180° 4 2 1o 'cl oc k 0° 1 or -3 0° IX1=d1 7o 'cl o 7 ck 15 0° o 'c o 2 loc r k 3 0 0 ° 3 o'clock 3 -90° or 270° 9 o'clock 9 90° 8 o ' 1 8 clo 2 c 0 k ° ° k c lo 'c o 10 12 o'clock 0 or 12 0° Ib 8 o ' 1 8 cl o 2 c 0 k ° 12 o'clock 0 or 12 0° 2 I X 3 7o 'cl o 7 ck 15 0° k loc o'c 11 11 ° 30 1 ° 0 -6 0 Ia Ic 2 IH k loc o'c 11 11 ° 30 1o 'cl oc 33 k 0° 1 or -3 0° IX 1= Ia -Ic -Ic k 9 o'clock 9 90° 3 o'clock 3 -90° or 270° 7o 'cl o 7 ck 15 0° 0 c IB IC 1 lo 2 12 o'clock 0 or 12 0° 5 7 0 ° D1d1 = Dd0 o 'c lo c 3 k 6o 'cl o 6 ck 18 0° 5 o'clock 5 -150° or 210° k oc 'cl ° 4 o 4 240 r °o 20 -1 o 'c lo c k 3 r2 o ° ° 0 7 0 -9 Figure 49: Delta-Delta Transformer Phasors 57 The Relay Testing Handbook The next transformer is a Wye-Delta transformer with a Wye side primary because the Wye side, H-Bushing CTs are connected to 47, 49, 51, 46, 48, and 50. CT1 400:5 CT2 1200:5 H1 PHA IH1=0º IA @ 0 º º 0 @ a I IB @ -1 2 0 º º 0 2 1 @ b I IC @ º 0 2 1 @ Ic X1 H2 IX1=Ia-Ic@-30º X2 PHB IH2@-120º H3 PHC IH3@120º 1 2 0 º IX2@-150º X3 IX3@90º H0 47 1A 46 49 1B 48 51 55 1C 57 2A 50 59 2B 54 56 2C 58 BECKWITH ELECTRIC M-3310 Figure 50: Wye-Delta Transformer Connections Starting with the Wye currents, draw a phasor diagram of the current flowing through the primary bushings (IH1, IH2, & IH3) which are equal to the phase (IA, IB, & IC) currents as shown in the first phasor diagram. The current flowing through X1 is “Ia and -Ic” because X1 is connected to the polarity winding of the aØ winding and the non-polarity of the cØ winding. The secondary current is plotted in the second phasor diagram 180º from the actual current flowing into the relay to make the relationship between windings easier to understand. The second phasor diagram demonstrates the Ia and -Ic addition and the final result “IX1” which is found at the 1 o’clock position or -30º. The third phasor diagram displays the relationship between the primary and secondary windings which can be translated to “Y0d1” or “Yd1” using correct notation. k loc o'c 11 11 30° 12 o'clock 0 or 12 0° IA=IH1 k oc 'cl o 10 ° 0 0 6 1 k loc o'c 11 11 30° 1o 'clo ck 330 ° o1 r30° -6 0 ° 2 o 'cl o 2 ock r 3 00 ° 9 o'clock 9 90° 3 o'clock 3 -90° or 270° 8 1 8 20 ° o' cl oc k 4 7o 'clo 7 ck 150 ° 6 o'clock 6 180° ck 'clo 5 o 5 210° or 0° -15 k oc 'cl o 10 ° 0 0 6 1 ° k oc 40 2 'cl o 4 or ° 0 12 - k loc o'c 11 11 30° 1o 'clo ck 330 ° o1 r30° IX1 =Ia -Ic -Ic -6 0 ° Ia 2 o 'cl o 2 ock r 3 00 ° I X 3 9 o'clock 9 90° 3 o'clock 3 -90° or 270° 8 o' c 1 8 loc 20 k ° IX2 7o 'clo 7 ck 150 ° IH1=Y0 k oc 'cl o 10 ° 0 0 6 1 1o 'c 330 1 lock ° o r30° IX 1= d1 -6 0 ° 2 o 'cl o 2 ock r 3 00 ° o'clock 9 90° 3 o'clock 3 -90° or 270° 6 o'clock 6 180° ck 'clo 5 o 5 210° or 0° -15 4 ° k oc 40 2 'cl o 4 or ° 0 12 - Y0d1 = Yd1 8 o' c 1 8 loc 20 k ° 4 7o 'clo 7 ck 150 ° Figure 51: Wye-Delta Transformer Phasor Diagrams 58 12 o'clock 0 or 12 0° Ib Ic 2 IH = IB IC = IH 3 12 o'clock 0 or 12 0° 6 o'clock 6 180° ck 'clo 5 o 5 210° or 0° -15 ° k oc 40 2 'cl o 4 or ° 0 12 - Chapter 2: Percent Dif ferential (87) Element Testing The next example is a Wye-Delta transformer with a different delta configuration. The Wye or high voltage winding is the primary winding because the Wye side CTs are connected to the SEL-587 relay terminals Z01, Z03, Z05, Z02, Z04, and Z06. CT2 1200:5 CT1 400:5 H1 PHA IH1=0º IA @ 0 º º 0 @ Ia IB @ 2 1 0 º º 0 2 1 @ b I X1 H2 IX1=Ia-Ib@30º X2 PHB IH2@-120º H3 PHC IH3@120º IX2@-90º X3 IX3@150º IC @ 1 2 0 º º 0 2 1 @ Ic H0 101 IA W 1 103I 105I 107I 109I 111I 104 106 108 110 112 B W 1 102 C W 1 B W 2 A W 2 C W 2 SCHWEITZER ENGINEERING LABORATORIES SEL-587 Figure 52: Wye-Delta Alternate Transformer Connections Starting with the Wye currents, draw a phasor diagram of the current flowing through the primary bushings (IH1, IH2, & IH3) which are equal to the phase (IA, IB, & IC) currents as shown in the first phasor diagram. The second phasor diagram displays the Delta-winding phasors with the phase currents in phase with the Wye-connected winding and the line current equal to “Ia-Ib” because the X1 bushing is connected tothe aØ winding and the bØ non-polarity winding. The third phasor shows the phase relationship between windings and can be described as Y0d11 or “Yd11”. k loc o'c 11 11 ° 30 o cl 0 1 ck 12 o'clock 0 or 12 0° IA=IH1 °o 'cl o 1 ck r30 ° -6 ' o 10 ° 0 6 2 0 ° o 'c o 2 loc r k 3 0 0 ° 9 o'clock 9 90° 3 o'clock 3 -90°or 270° 8 1 2 8 0 ° o 'c lo c k 4 7o 'cl o 7 ck 15 0° 6 o'clock 6 180° ock 'cl 5 o 5 210° r °o 50 -1 1 ck lo 'c o 0 ° 0 1 60 1 IX ° ck 0 4 lo 2 'c o 4 or ° 0 2 -1 k loc o'c 11 11 ° 30 1o 'cl oc 33 k 0° 1 or -3 0° -6 0 Ib a=I -Ib 2 ° Ia o 'c o 2 loc r k 3 0 0 ° 9 o'clock 9 90° 3 o'clock 3 -90°or 270° 8 o ' 1 8 cl o 2 c 0 k ° 4 7o ' cl o 7 ck 15 0° 1 ck lo 'c o 0 ° 0 1 60 12 o'clock 0 or 12 0° IH1=Y12 1 IX 33 1o 'cl oc k 0° 1 or -3 0° -6 0 11 =d 2 ° o 'c o 2 loc r k 3 0 0 ° 9 o'clock 9 90° 3 o'clock 3 -90°or 270° Ib Ic 2 IH = IB IC = IH 3 12 o'clock 0 or 12 0° k loc o'c 11 11 ° 30 1o 33 0 6 o'clock 6 180° ock 'cl 5 o 5 210° r °o 50 -1 ° ck 0 4 lo 2 'c o 4 or ° 0 2 -1 Y0d11= Yd11 8 o ' 1 8 clo 2 c 0 k ° 4 7o 15 'cl o 7 ck 0° 6 o'clock 6 180° ock 'cl 5 o 5 210° r °o 50 -1 ° ck 0 4 lo 2 'c o 4 or ° 0 2 -1 Figure 53: Wye-Delta Alternate Transformer Phasor Diagrams 59 The Relay Testing Handbook The example in Figure 50 can easily become a Delta-Wye transformer by switching the protective relay connections as shown in the next example. CT1 CT2 400:5 H1 PHA IH1=0º 1200:5 IA @ 0 º º 0 @ Ia IB @ -1 2 º 0 2 1 @ Ib IC @ 1 2 0 º º 0 2 1 H2 X1 IX1=Ia-Ic@-30º X2 PHB IH2@-120º H3 º 0 PHC IH3@120º IX2@-150º X3 IX3@90º @ Ic H0 55 1A 54 57 59 1B 56 47 1C 2A 58 46 49 2B 48 51 2C 50 BECKWITH ELECTRIC M-3310 Figure 54: Delta-Wye Transformer Connections You should always start with the Wye-winding and the phase and line currents are drawn in the second phasor diagram because the Wye-winding is the secondary winding. 60 Chapter 2: Percent Dif ferential (87) Element Testing The first diagram follows the steps from Figure 50 for the Delta-winding because it is now the primary winding. The third diagram displays the phasor relationship between windings and the transformer is described as D1y0 based on this diagram. The primary winding must always be at 12 o’clock and we can rotate the phasors or the clock to obtain the correct description D0y11 or “Dy11” as shown in the fourth and fifth phasor diagrams. k c 0 1 k loc o'c 11 11 ° 0 3 12 o'clock 0 or 12 0° 1o 'cl oc 33 k 0° 1 or -30 ° IX 1= Ia-Ic I lo 'c o 10 ° 0 6 -6 c 0 ° 9 o'clock 9 90° o 'c o 2 loc r k 3 0 0 ° 1 3 o'clock 3 -90° or 270° 8 2 8 0 ° lo 'c o 10 ° 0 6 4 ck 'clo 5 o 5 210° or 0° -15 6 o'clock 6 180° k loc o'c 11 11 ° 30 1 0 c lo 'c o 10 ° 0 6 8 -6 0 1 y1 1= IH ° 4 c k 7o ' 7 clock 15 0° 6 o'clock 6 180° o 'c o 2 loc r k 3 0 0 ° = 2 1 6 o'clock 6 180° ck 'clo 5 o 5 210° or 0° -15 2 o 'c o 2 loc r k 3 0 0 ° 9 ck 'clo 5 o 5 r 210° o 0° -1 5 o ck lo 'c 4 -1 0 2 ° r o 2 4 ck lo 'c o 9 0 k loc o'c 11 11 ° 0 3 k 'c o 10 ° 0 6 -6 0 2 ° o 'c o 2 loc r k 3 0 0 ° 9 o'clock 9 90° 3 o'clock 3 -90° or 270° k ° c 0 4 lo 2 'c o 4 or ° 0 2 -1 8 1 11 o'clock 11 30° 4 ck 6 o'clock 6 180° ck 'clo 5 o 5 210° or 0° -1 5 o k c lo 'c 4 -1 2 ° 0 r o 2 4 0 ° 12 o 0 o 'clo ck r 0° 12 IH1=y11 ° D1y0 o 'c lo 7o 'cl o 7 ck 15 0° IX 0 9 2 8 0 ° 1= D0 -3 0 ° 1 o 'c o 1 loc r k 3 3 0 ° 2 o'clock 2 -60° or 300° 7 1 1o 'cl oc 33 k 0° 1 or -30 ° IX 1= D1 IH1=y0 8 o'clock 8 120° ° 0 12 o'clock 0 or 12 0° IB k loc o'c 10 10 ° 60 D0y11 = Dy11 o 'c lo IH 1o 'cl oc 33 k 0° 1 or -3 0° 3 o'clock 3 -90° or 270° 2 8 0 ° 0 ° 4 9 o'clock 9 90° 1 = IC 7o 'cl o 7 ck 15 0° 12 o'clock 0 or 12 0° -6 c lo 2 3 o'clock 3 -90° or 270° 8 o ' 1 8 clo 2 ck 0 ° IX1=D0 1o 'cl oc 33 k 0° 1 or -30 ° 9 o'clock 9 90° k ° c 0 4 lo 2 'c o 4 or ° 0 2 -1 k 12 o'clock 0 or 12 0° IH1=IA IH 3 o 'c lo ck 7o 'cl o 7 ck 15 0° 0 Ib Ic 1 k c 2 Ia k loc o'c 11 11 ° 0 3 5 7 0 ° D0y11= Dy11 o 'c lo c k 3 6o ' 6 c lock 18 0° 5 o'clock 5 -150°or 210° ck 'clo 4 o 4 r 240° o 0° -12 ° ck 0 lo 7 'c o 3 r2 o ° 0 -9 Figure 55: Delta-Wye Transformer Connections 61 The Relay Testing Handbook The example in Figure 52 can easily become a Delta-Wye transformer by switching the protective relay connections as shown in the next example where the Delta-winding is connected to SEL-387 terminals Z01, Z03, Z05, Z02, Z04, and Z06 CT2 CT1 1200:5 400:5 H1 PHA IH1=0º IA @ 0 º º 0 @ Ia IB @ -1 2 0 º º 0 2 1 @ Ib IC @ 1 2 0 º º 0 2 1 @ Ic H2 X1 IX1=Ia-Ib@30º X2 PHB IH2@-120º H3 PHC IH3@120º IX2@-90º X3 IX3@150º H0 Z07 I Z09 I Z11I Z01 I Z03 I Z05I Z08 Z10 Z12 Z02 Z04 Z06 A W 1 B W 1 C W 1 A W 2 B W 2 C W 2 SCHWEITZER ENGINEERING LABORATORIES SEL-387 Figure 56: Delta-Wye Alternate Transformer Connections Starting with the Wye currents, draw a phasor diagram of the current flowing through the primary bushings (IH1, IH2, & IH3) which are equal to the phase (IA, IB, & IC) currents as shown in the second phasor diagram. The first phasor diagram displays the Delta-winding phasors with the phase currents in phase with the Wye-connected winding and the line current equal to “Ia-Ib” because the X1 bushing is connected tothe aØ winding and the bØ non-polaritywinding. 62 Chapter 2: Percent Dif ferential (87) Element Testing The third diagram displays the phasor relationship between windings and the transformer is described as D11y0 based on this diagram. The primary winding must always be at 12 o’clock and we can rotate the phasors or the clock to obtain the correct description D0y1 or “Dy1” as shown in the fourth and fifth phasor diagrams. 12 o'clock 0 or 12 0° k loc o'c 11 11 ° 30 ck lo 'c o 0 10 1 60° Ib Ia1= -Ib IX k loc o'c 11 11 ° 30 1o 'c l oc 33 k 0° 1 or -3 0° Ia 9 o'clock 9 90° 9 o'clock 9 90° 3 o'clock 3 -90°or 270° IB 8 o 'c 2 8 loc 0 k ° 4 7o 'cl o 7 ck 15 0° 6 o'clock 6 180° k oc 'cl ° 5 o 5 210 r °o 50 -1 ck lo 'c o 4 0 2 -1 r o ° ° 0 4 2 = IH 8 1 4 'cl o 7 ck 15 0° 12 o'clock 0 or 12 0° k loc o' c 11 11 ° 30 ck lo 'c o 0 ° 0 1 60 1 IX1=D0 IH -6 0 ° ck lo 'c o 1 ° 1 1 30 1 2 o 'c o 2 loc r k 3 0 0 ° 9 o'clock 9 90° 3 o'clock 3 -90°or 270° D0y1 = Dy1 8 o ' 1 8 clo 2 ck 0 ° 4 7o ' cl o 7 ck 15 0° 6 o'clock 6 180° 6 o'clock 6 180° k oc 'cl ° 5 o 5 210 r °o 50 -1 ck lo 'c o 4 2 -1 r o ° 0 k oc ' cl ° 5 o 5 210 r °o 50 -1 ck lo 'c o 4 ° 0 2 -1 r o 0 4 2 0 ° 2 -6 o 0° o 2 'clo ck r 3 0 0 ° 3 o'clock 3 -90°or 270° o ' 1 8 clo 2 ck 0 ° 4 7o 'cl o 7 ck 15 0° 1 o'clock 1 330°or -30° D0 1= IH1=y1 IX 6 o'clock 6 180° k oc 'cl ° 5 o 5 210 r °o 50 -1 ck lo 'c o 4 2 -1 r o ° 0 ° 0 4 2 2o 'cl oc 30 k 0° 2 or -6 0° 2 7 0 ° 3 o r o 'c 3 lo ck -9 0 ° 4 o'clock 4 240°or -120° 9 9 IH1=y0 1o ' cl oc 33 k 0° 1 or -3 0° D11y0 8 10 o'clock 10 60° ° I 11 =D X1 9 o'clock 9 90° ° 0 4 2 k loc o'c 2 12 or 1 0 0° 1o 'cl oc 33 k 0° 1 or -3 0° 1= y1 3 o'clock 3 -90°or 270° o 'c 2 8 l oc 0 k ° 7o ck lo 'c o 0 10 1 60° 2 -6 o 0° o 2 'clo ck r 3 0 0 ° 2 IH = IB 3 12 o'clock 0 or 12 0° k l oc o'c 11 11 ° 30 1o ' cl oc 33 k 0° 1 or -3 0° IA=IH1 Ib Ic 1 ck lo 'c o 0 10 1 60° 2 -6 o 0° o 2 'cl o ck r 3 0 0 ° 12 o'clock 0 or 12 0° D0y1 = Dy1 o 'c 9 lo ck 8o ' cl o 8 ck 12 0° 7 o'clock 7 150° k oc 'cl 6o 6 0° 18 ° ck 0 5 lo 1 'c o 5 r5 o ° 0 1 2 Figure 57: Delta-Wye Alternate Transformer Phasor Diagrams 63 The Relay Testing Handbook 2) The Easy Way The easy way requires a single line drawing, three line drawings, or the transformer nameplate which should all have a set of symbols like that describe the phase relationship between windings. This symbol represents a Wye-connected winding and symbol represents a Delta-connected winding. These are the only two symbols you need to determine phase relationship after reviewing the CT connections to determine which winding the relay considers to be the pr imary winding. After the primary winding is determined, redraw its connection symbol with AØ at the 12 o’clock position as shown in the next example. Redraw the secondary winding symbol to the right of the primary winding with the same phase relationship as shown on the nameplate. The secondary winding symbol’s AØ position will be either in the 11, 12, or 1 o’clock position. You can use any phase at the 12 o’clock position tomake it easier to translate as long as the same phase is used for both windings. The following table displays the most common transformer connections and their phase relationships. 64 Chapter 2: Percent Dif ferential (87) Element Testing PHASESYMBOL A a C B c A 12 o’clock 1o ’cl 0 or 12 oc 33 k 0° 0o 1 r30 ° Aa Yy0 b a A a 11 k loc o’c 11 ° 30 c C B b C A a 11 A c b 12 o’clock 1 o’c 0 or 12 loc 33 k 0° 0 1 or -3 0° Aa C 11 B 12 o’clock 1 o’c 0 or 12 loc 33 k 0° 0 1 or -3 0° ck clo o’ 11 ° 30 aA c 11 ck clo o’ 11 ° 30 A a a B c b C B Dy11 12 o’clock 1o ’cl 0 or 12 oc 33 k 0° 0 1 or -3 aA 0° Yd11 c B c Yd1 b b A ck lo o’c 11 ° 30 a a A C Dd0 b C B 12 o’clock 1 o ’c 0 or 12 lo c 33 k 0° 0 1 or -3 0° Aa b c B A B c a C C DESCRIPTION k loc o’c 11 11 ° 30 11 k loc o’c 11 ° 30 12 o’clock 1 o’c 0 or 12 loc 33 k 0° 0 1 or -3 0° Aa Dy1 b Figure 58: Transformer Nameplate Phase Relationships 65 The Relay Testing Handbook 2. Settings The following differential settings are described below to help understand what each setting means. A) Enable Setting Many relays allow the user toenable or disable settings. Make sure that the element is ON or the relay may prevent you from entering settings. Ifthe element is not used, the setting should be disabled or OFF to prevent confusion. Some relays will also have ”Latched” or ‘Unlatched” options. A Latched option indicates that the output contacts will remain closed after a trip until a reset is performed and acts as a lockout relay. Unlatched indicates that the relay output contacts will open when the trip conditions are no longer present. This setting can also be applied by enabling individual windings such as the SEL-387 “E87n” setting where “n” is the winding number. If all of the E87W settings are set to “N”, differential protection is disabled. B) Number of Windings This setting defines the number of windings to be used for differential protection. At least two must be selected with a typical maximum of four windings. Determine the number of CT inputs used and ensure the correct number of windings is selected. C) Phase-Angle Compensation This setting defines the phase-angle compensation between windings as described in the previous section. Depending on the relay manufacturer, this setting could be defined in one step using a descriptor such as “TRCON=DABY”or each winding could be defined by “W1CTC=11” and “W2CTC=12”.This is the most important setting and MUST be correct. 66 Chapter 2: Percent Dif ferential (87) Element Testing A table of the most common transformer connections and relays can be found in the following table. CONNECTION GE/MULTILINSR 745 A C B c B c D/y330° a Yd1 c B A b a b C W1 Connection=Delta W1 Angle=0º W2 Connection=Wye W2 Angle=330º b A Dy11 Y/d30° W1 Connection=Wye W1 Angle=0º W2 Connection=Delta W2 Angle=30º a Dd0 C D/d0° W1 Connection=Delta W1 Angle=0º W2 Connection=Delta W2 Angle=0º b A C Y/y0° a Yy0 B c W1 Connection=Wye W1 Angle=0º a A b Yd11 C B Y/d330° c A D/y30° c C B b W2 Connection=Delta W2 Angle=330º W1 Connection=Delta a Dy1 GET 60,T 30 W1 Connection=Wye W1 Angle=0 W2 Connection=Wye W2 Angle=0 W1 Angle=0º W2 Connection=Wye W2 Angle=30º 67 The Relay Testing Handbook BECKWITH ELECTRIC CONNECTION A a Yy0 C B c b A C b A W1CTC=12 W2CTC=12 CTCON=YY Transformer Connection 10. DACDACyy W1CTC=0 W2CTC=0 Transformer Connection 02. YDACyy W1CTC=12 W2CTC=1 TRCON=YDAC Transformer Connection 05. DACYyy W1CTC=0 W2CTC=11 TRCON=DACY Transformer Connection 03. YDAByy W1CTC=12 W2CTC=11 TRCON=YDAB Transformer Connection 04. DABYyy W1CTC=0 W2CTC=1 TRCON=DABY CTCON=YY TRCON=YY CTCON=YY a c C B A CTCON=YY b a b C B c CTCON=YY a A Yd11 b C B c A CTCON=YY a c C Transformer Connection 01. Yyyy TRCON=DACDAC B c Yd1 Dy1 SEL 587 a Dd0 Dy11 SEL 387 M 3310 B b Figure 59: Common Phase-Angle Compensation Settings D) MVA This setting is used in conjunction with the Winding Voltage setting to automatically calculate the Tap values for each winding. Different engineers use different criteria for the MVA setting (minimum MVA, nominal MVA, maximum MVA) but the setting should NEVER exceed the maximum transformer MVA. E) Winding Voltage This is used in conjunction with the MVA setting to automatically calculate the Tap valuessetting for each winding. 68 Chapter 2: Percent Dif ferential (87) Element Testing F) Minimum Pickup (Restrained) The Minimum Pickup setting is used to provide more stability to the differential element by requiring a minimum amount of current to flow before the differential element will operate. This minimum operate current is used to prevent nuisance trips due to noise or metering errors at low current levels. This setting should be set around 0.3 x the nominal or Tap current of the protected device. G) Tap The Tap setting defines the normal operate current based on the rated load of the protected equipment, the primary voltage, and the CT ratio. This setting is used as the per-unit operate current of the protected device and most differential settings are based on the Tap setting. Verify the correct Tap setting using the following formula. TAP = CTSEC × Power P-P Volts × 3 ×CT PRI H) Slope-1 The Slope-1 setting sets the ratio of operate current to restraint current that must be exceeded before the 87-Element will operate as described previously. The slope setting is typically set at 20-30%. I) Slope-2 The Slope-2 setting sets the ratio of operate current to restraint current that must be exceeded before the 87-Element will operate if the restraint current exceeds a pre-defined or user-defined breakpoint between Slope-1 and Slope-2. J) Breakpoint This setting defines whether Slope-1 or Slope-2 will be used to determine if the relay should trip. The Breakpoint is defined as a multiple of Tap and if the restraint current exceeds the Breakpoint setting, the 87-Element will use Slope-2 for its calculation. K) Time Delay The Time Delay setting sets a time delay (typically in cycles) between an 87-Element pickup and trip. The Time Delay is typically setat the minimum possible setting but can be set as high as three cycles for maximum reliability on some relays. 69 The Relay Testing Handbook L) Block The block setting defines a condition that will prevent the differential protection from operating such as a status input from another device. This setting is rarely used. If enabled, make sure the condition is not true when testing. Always verify correct blocking operation by operating the end-device instead of a simulation to ensure the block has been correctly applied. M) Harmonic Inhibit Parameters This setting determines what harmonic the differential protection will use to detect transformer inrush or over-excitation which could cause a nuisance trip. This setting is typically set for 2nd, 4th, or 5th harmonics. 3. Current Transformer Connections Zones of protection are defined by the CT locations which makes the CT connections the most important aspect of transformer differential protection. The CT ratio, polarity, and location must match the manufacturer’s requirements and relay settings, or the differential protection may never work correctly. CT connections are confusing for some people, but the connections can be correctly interpreted by following the flow of power. Use the following figures to determine the correctconnections for our examples. Power flows from the generator to the system in this application so we can trace the flow of power from “To Generator” to “To System.” Current flows into the CT polarity mark and out the CT secondary polarity mark (or H1 & X1). Follow the line from the polarity mark to relay terminal H1. Current flows through the relay coil and exits the relay from terminal G1. Follow G1 back to the CT to ensure the CT secondary connections are a closed loop. Repeat this step for the other two phases and ground, if applicable. Using this procedure on Figure 60 we discover that the Generator AØ(1A) current flows into H1, BØ(1B) flows into H2, and CØ(1C) flows into H3. 70 Chapter 2: Percent Dif ferential (87) Element Testing The secondary current flows from “Winding No. 2” to “To System” and flows into the nonpolarity mark of the CT. The secondary current flows out of the non-polarity mark, through the two neutral jumpers and into G4. The current flows through the relay and out H4 to the CT polarity mark. Using this procedure on Figure 60we discover that the System AØ(2a) current is connected to H4, BØ(2b) to H5, and CØ(2c) to H6. Figure 60: Zones of Protection Example 71 The Relay Testing Handbook Another way to quickly determine correct CT polarity is to pick a reference point and compare the manufacturer’s drawings to the application drawings. Choose the CT side away from the transformer in the examples and follow them to H1, H2, and H3 for each phase. Choose the CT side facing away from the transformer on the secondary side and follow the wiring to H4, H5, and H6. Always ensure that the CTs are a closed loop and that only one grounding point is connected for each isolated circuit. Many peopleget fixated on the polarity marks which, as shown in Figures 61 and 62, are not as important as the actual CT connections. CT1 400:5 H1 X1 CT2 1200:5 PHA H2 X2 H3 X3 PHB PHC X0 H1 H2 1A G1 H3 1B G2 H4 1C H5 2A G3 G4 2B G5 H6 2C G6 GE/MULTILIN-745 Figure 61: CT Connections Example #1 CT1 CT2 400:5 1200:5 H1 X1 H2 X2 H3 X3 PHA PHB PHC X0 H1 1A G1 H2 1B G2 H3 H4 1C 2A G3 G4 GE/MULTILIN-745 Figure 62: CT Connections Example #2 72 H5 2B G5 H6 2C G6 Chapter 2: Percent Dif ferential (87) Element Testing The following figures represent the connection drawings for the most popular differential relays applied today. Figure 63: GE/Multilin SR-745 Transformer Protective Relay Connections Figure 64: GE T-60 Transformer Protective Relay Connections 73 The Relay Testing Handbook Figure 65: Beckwith Electric M-3310 Transformer Protective Relay Connections Figure 66: Schweitzer Electric SEL-587 Transformer Protective Relay Connections 74 Chapter 2: Percent Dif ferential (87) Element Testing Figure 67: Schweitzer Electric SEL-387 Transformer Protective Relay Connections 4. 3-Phase Restrained-Differential Pickup Testing Performing differential pickup testing is very similar to the test procedure for overcurrent protection with a few extra phases to test. Because 3-phase transformers typically have correction factors to compensate for transformer phase shifts, Minimum Pickup tests should be performed using 3-phase balanced currents. The test is performed by applying and raising current in one winding until the element operates. Repeat for all differential windings. You must determine what the expected result should be before performing any test. Record the Pickup and Tap settings. If the relay does not have a Tap setting, refer to the manufacturer’s literature to determine if the relay uses some other nominal setting such as rated secondary current (5A usually). Multiply the Pickup and Tap settings to determine the Minimum Pickup in amps. 75 The Relay Testing Handbook We will use an SEL-387E relay with the following differential settings for the rest of the tests in this chapter. Winding-1 CTR_ (CT Ratio) MVA (XFMR MVA Ration) W_CTC (Winding Connection) VWDG_ (Winding Voltage) 240 Tap_ O87P SLP1 SLP2 IRS1 2.41 Winding-2 1600 230 12 1 230 18 0.30 4.61 20 60 3.0 This relay has a Minimum Pickup setting (O87P) and we can determine the three-phase Minimum Pickup using the formula O87P × TAP . It’s always a good idea to verify the Tap settings as described in the previous chapter using the transformer nameplate as shown below for this transformer. W IN D IN G 1 TAP1 = CTSEC × Power P-P Volts × 3 ×CT PRI TAP1 = 1 × 230,000 ,000 230,000 × 3 ×24 0 TAP1 = 2.40569 WIN D IN G 2 TAP2 = CTSEC × Power P-P Volts × 3 ×CT PRI TAP2 = 1 × 230,000 ,000 18,000 × 3 ×16 00 TAP2 = 4.6109 The Tap settings appear to be appropriate for the application and are very close to the SEL387E generated Tap settings. We can determine the Minimum Pickup for each winding with the following formula. 76 W IN D IN G 1 WIN D IN G 2 Minimum Pickup = O87P × Tap Minimum Pickup = O87P × Tap Minimum Pickup = 0.3 × 2.41 Minimum Pickup = 0.3 × 4.61 Minimum Pickup = 0.723A Minimum Pickup = 1.383A Chapter 2: Percent Dif ferential (87) Element Testing A) 3-Phase Test-Set Connections Connect all three phases to one winding. Afterall Winding-1 tests are completed, movethe test leads to Winding-2 and repeat. RELAY INPUT CØ AØ RELAY TEST SET RELAY WINDING 1 A Phase Amps B Phase Amps C Phase Amps WINDING 2 A Phase Amps B Phase Amps C Phase Amps Element Output BØ Ma g n it u d e + + + + + + IAW1 Amps P h a se A ng l e Frequency IAW1TestAmps 0° Test Hz IBW1 Amps IBW1 Test Amps -120° (240°) ICW1 Amps ICW1TestAmps 120° Timer Input Element Output Test Hz TestHz + + + + + Alternate Timer Connection + DC Supply - Timer Input + Figure 68: Simple 3-Phase 87-Element Test-Set Connections If your test-set has six available current channels, you can use the following connection diagram, and change the output channel for each test until all pickup values have been tested. W1 RELAY INPUT ICW1Ø W2 RELAY INPUT ICW2Ø IAW1Ø IBW1Ø RELAY WINDING 1 A Phase Amps B Phase Amps C Phase Amps IAW2Ø IBW2Ø RELAY TEST SET Ma gn it ud e + + + + + + B Phase Amps C Phase Amps 0° Test Hz IBW1 Amps IBW1 Test Amps -120° (240°) Test Hz ICW1 Amps ICW1TestAmps TestHz 120° (PS = Phase Shift) WINDING 2 A Phase Amps Ph aseAn gl e Frequency IAW1 Amps IAW1TestAmps + + + + + + IAW2 Amps IAW2TestA mps IAW1°+PS TestH z IBW2 Amps IBW2TestAmps IBW1°+PS TestHz ICW2 Amps ICW2 Test Amps ICW1°+PS Test Hz Alternate Timer Connection + DC Supply - Element Output + + Timer Input Element Output + Timer Input Figure 69: Simple 3-Phase 87-Element T est-Set Connections with Six Current Channels 77 The Relay Testing Handbook B) 3-Phase Pickup Test Procedure Use the following steps to determine pickup. 1. Determine how you will monitor pickup and set the relay accordingly, if required. (Pickup indication by LED, output contact, front panel display, etc…See previous packages of The Relay Testing Handbookfor details.) 2. Group all three currents together so that you can change the magnitude of all three simultaneously while maintaining 120º between phases. Set the test cur rent 5% higher than the pickup setting as shown in the following table. WIN D IN G 1 W I N DI N G 2 Min Pickup × 105% = Test Amps Min Pickup × 105% = Test Amps 0.723A × 1.05 = Test Amps 1.383A × 1.05 = Test Amps 0.75915A 1.452A 0.759A@0º 0.759A@240º 0.759A@120º 1.452A@0º 1.452A @240º 1.452A @120º AØ Test Amps BØ Test Amps CØ Test Amps 3. Apply 3-Phase test current and make sure pickup indication operates. 4. Slowly lower all three currents simultaneously until the pickup indica tion is off. Slowly raise the currents until pickup indication is fully on (Chattering contacts or LEDs are not considered pickup). Record the pickup values on your test sheet. The following graph displays the pickup procedure. 5A ELEMENT PICK-UP 4A 3A 2A PICKUP SETTING 1A STEADY-STATE PICKUP TEST Figure 70: Pickup Test Graph 78 Chapter 2: Percent Dif ferential (87) Element Testing 5. Compare the pickup test result to the manufacturer’s specifications and calculate the percent error as shown in the following example. The 87-Element pickup setting is 0.723A and the measured pickup was 0.731A. Looking at the “Differential Element” specification in Figure 71, we see that the acceptable metering error is ±5% ±0.10A. Differential Element Unrestrained Pickup Range: Restrained Pickup Range: 1–20 in per unit of tap 0.1–1.0 in per unit of tap Pickup Accuracy (A secondary) 5 A Model: 1 A Model: ±5% ±0.10 A ±5% ±0.02 A Unrestrained Element Pickup Time (Min/Typ/Max): 0.8/1.0/1.9 cycles Restrained Element (with harmonic Blocking) Pickup Time (Min/Typ/Max): 1.5/1.6/2.2 cycles Restrained Element (with harmonic Restraint) Pickup Time (Min/Typ/Max): 2.62/2.72/2.86 cycles Figure 71: SEL-387E Specifications We can calculate the manufacturer’s allowable percent error for Winding-1. 100 × (5% ×Se tting ) + 0.1A 100 × Setting (5% ×0. 723 ) + 0.1A 0.723 = Allowable Percent Error = Allowable Percent Error 18.831 % Allowable Percent Error The measured percent error can be calculated using the percent error formula below. Actual Value - Expected Value × 100 = Percent Error Expected Value 0.731A - 0.723A × 100 = Percent Error 0.723A 1.1% Error The Winding-1 test is within the manufacturer’s tolerance and passed the test. 6. Repeat the pickup test for all windings that are part of the differential scheme. 79 The Relay Testing Handbook DIFFERENTIAL TEST RESULTS PICK UP 0.3 TIME DELAY 0 SLOPE 1 20% TAP1 2.41 SLOPE 2 60% TAP2 4.61 MINIMUM PICK UP TESTS (Amps) P3HASE MFG ERROR % W1 PICKUP 0.731 0.723 1.11 W2 PICKUP 1.398 1.383 1.08 W3 PICKUP NA NA C) 1-Phase Test-Set Connections The most basic test-set connection uses only one phase of the test-set with a test lead change between every pickup test. After the Winding-1 A-phase pickup test is performed, move the test leads from Winding-1 A-Phase amps to B-Phase amps and perform the test again. Repeat until all enabled phases are tested on all windings. RELAY INPUT AØ PU RELAY WINDING 1 A Phase Amps RELAY TEST SET A Phase Input=Pickup M a g n i t ud e + + + + + + C3 Amps + Timer Input B Phase Amps C Phase Amps C1 Amps AØTestAmps P h a s eA ng l e Frequency 0° Test Hz C2 Amps WINDING 2 A Phase Amps B Phase Amps C Phase Amps Element Output + + + + Alternate Timer Connection + DC Supply Element Output + Figure 72: Simple 87-Element Test-Set Connections 80 Timer Input Chapter 2: Percent Dif ferential (87) Element Testing You can also connect all three phases to one winding and change output channels instead of changing leads. After all Winding-1 tests are completed, move the test leads to Winding-2 and repeat. TEST #1 RELAY INPUT TEST #2 RELAY INPUT TEST #3 RELAY INPUT AØ PU BØ PU CØ PU RELAY TEST SET RELAY WINDING 1 A Phase Amps B Phase Amps C Phase Amps Mag n i t u d e + + + + + + P h as e An g l e Frequency C1 Amps AØTestAmps 0° C2 Amps BØTestAmps 0° TestHz C3 Amps CØTestAmps 0° TestHz Test Hz WINDING 2 A Phase Amps B Phase Amps C Phase Amps + + + Alternate Timer Connection DC Supply + Element Output + + Timer Input - Element Output Timer Input + Figure 73: Simple 3-Phase 87-Element Test-Set Connections If your test-set has six available current channels, you can use the following connection diagram and change the output channel for each test until all pickup values have been tested. TEST #1 RELAY INPUT TEST #2 RELAY INPUT TEST #3 RELAY INPUT TEST #4 RELAY INPUT TEST #5 RELAY INPUT TEST #6 RELAY INPUT A1Ø PU B1Ø PU C1Ø PU A2Ø PU B2Ø PU C2Ø PU RELAY WINDING 1 A Phase Amps B Phase Amps C Phase Amps RELAY TEST SET + + + + + + + + + + + + Magnit ude Ph as e Angle Frequency C1 Amps A1ØTestAmps 0° C2 Amps B1ØTestAmps 0° TestHz Test Hz C3 Amps C1ØTestAmps 0° TestHz C4 Amps A2ØTestAmps 0° TestHz C5 Amps B2ØTestAmps 0° TestHz C6 Amps C2Ø Test Amps WINDING 2 A Phase Amps B Phase Amps C Phase Amps 0° TestHz Alternate Timer Connection DC Supply + Element Output + + Timer Input Element Output + Timer Input Figure 74: Simple 3-Phase 87-Element Test-Set Connections with Six Current Channels 81 The Relay Testing Handbook D) 1-Phase Pickup Test Procedure A single-phase test procedure is slightly more complicated because correction factors may apply. Digital transformer relays use algorithms to compensate for the different transformer phase shifts as described earlier and apply compensation factors to compare windings with different configurations. The compensation factors for the example SEL387 can be found in the Testing and Troubleshooting section of the instruction manual as shown in the following table. WnCTC S E T TIN G A 0 1 Odd:1,3,5,7,9,11 √3 Even:2,4,6,8,10,12 1.5 However, the table does not seem to be correct when the WnCTC equals 12. We have found through experimentation that the correction factor is 1 when WnCTC equals 12. Use the following steps to determine pickup. 1. Determine how you will monitor pickup and set the relay accordingly, if required. (Pickup indication by LED, output contact, front panel display, etc…See previous packages of The Relay Testing Handbookfor details.) 2. Determine the expected pickup: W IN D IN G 1 MinimumPickup = WI N D IN G 2 O87P × TAP1 × A MinimumPickup = O87P × TAP2 × A 0.3 ×2.41 ×( W1 CTC(12))1 MinimumPickup = 0.3 × 4.61 ×( W1 CTC(1)) 3 MinimumPickup = MinimumPickup = 0.723 MinimumPickup = 2.395 3. Set the fault current 10% higher than the pickup setting. For example, set the fault current at 0.795A (0.723 × 1.1 = 0.795A ) for Winding-1 or 2.634A (2.395 × 1.1 = 2.634A ) for Winding-2. Make sure pickup indication operates. 4. Slowly lower the current until the pickup indication is off. Slowly raise current until pickup indication is fully on (Chattering contacts or LEDs are not considered pickup). Record the pickup values on your test sheet. The following graph displays the pickup procedure. 82 Chapter 2: Percent Dif ferential (87) Element Testing 5A ELEMENT PICK-UP 4A 3A 2A PICKUP SETTING 1A STEADY-STATE PICKUP TEST Figure 75: Pickup Test Graph 5. Compare the pickup test result to the manufacturer’s specifications and calculate the percent error as shown in the following example. The 87-Element pickup Winding-2 pickup setting is 2.395A and the measured pickup was 2.421A. Looking at the “Differential” specification in Figure 76, we see that the acceptable metering error is ±5% ±0.10A. Figure 76: SEL-387E Specifications 83 The Relay Testing Handbook We can calculate the manufacturer’s allowable percent error for Winding-2. 100 × (5% ×Se tting ) + 0.1A 100 × Setting (5% × 2.395 ) + 0.1A 2.395 100 × 0.21975 = Allowable Percent Error = Allowable Percent Error = Allowable Percent Error 2.395 9.18% Allowable Percent Error The measured percent error can be calculated using the percent error formula below. Actual Value - Expected Value × 100 = Percent Error Expected Value 2.421A - 2.395A × 100 = Percent Error 2.395A 1.1% Error The Winding-2 test is within the manufacturer’s tolerance of 9.18% and passed the test. 6. Repeat the pickup test for all phase currents that are part of the differential scheme DIFFERENTIAL TEST RESULTS PICK UP 0.3 SLOPE 1 20% TIME DELAY TAP1 2.41 W1CTC 12 SLOPE 2 60% TAP2 4.61 W2CTC 1 0 MINIMUM PICK UP TESTS (Amps) A PHASE W1 PICKUP W2 PICKUP W3 PICKUP 0 .7 3 1 2.421 NA B PHASE 0.732 2.422 NA C PHASE 0.730 2.425 NA MFG % ERROR 0.723 1 . 11 1. 24 2.395 1 . 07 1. 11 0. 97 1.24 NA 5. Restrained-Differential Timing Test Procedure It is very important to ensure that all phases are assigned to operate the output contact because some relays, such as the SEL-387, allow the designer differential tripsor f each individually . For example, the SEL-387 wor d bit “87R1” to is assign an A-Phase differential trip andphase “87R” is a differential trip on any phase. Assigning the incorrect word bit to the final output is an easy mistake that has occurred in the field. I strongly recommend performing single-phase timing 84 Chapter 2: Percent Dif ferential (87) Element Testing tests on every current-input connected to the differential element using the final trip output to ensure that the relay trips on all phases and all windings. The timing test procedure is very straightforward. Apply a single-phase current 10% greater than the Minimum Pickup setting into each input related to the percent differential element and measure the time between the applied current and the relay trip signal. As with all tests, we first must discover what an acceptable result is. Use Figure 77 to determine the acceptable tolerances from the manufacturer’s specifications. Differential Element Unrestrained Pickup Range: 1–20 in per unit of tap Restrained Pickup Range: 0.1–1.0 in per unit of tap Pickup Accuracy (A secondary) 5 A Model: 1 A Model: ±5% ±0.10 A ±5% ±0.02 A Unrestrained Element Pickup Time (Min/Typ/Max): 0.8/1.0/1.9 cycles Restrained Element (with harmonic Blocking) Pickup Time (Min/Typ/Max): 1.5/1.6/2.2 cycles Restrained Element (with harmonic Restraint) Pickup Time (Min/Typ/Max): 2.62/2.72/2.86 cycles Output Contacts: Standard: Make: 30 A; Carry: 6 A continuous carry at 70°C, 4 A continuous at85°C: 1 s Rating: 50 A: MOV protected: 270 Vac, 360 Vdc, 40 J; Pickup time: Less than 5 ms; Dropout time: Less than 5 ms typical. Breaking Capacity (10000 operations): Figure 77: SEL-387 Differential and Output Relay Specifications The time delay setting for our example is 0 cycles which means that there is no intentional delay. However, there are software and hardware delays built into the relay that must be accounted for. Figure 78 indicates that the maximum allowable timeis 60ms or 3.6 cycles. DELAY REASON Restrained Element (with harmonic restraint) Pickup 2.86 cycles (47.7 ms) Time (Max) [Software] Output Contacts Operate Time [Hardware] 5 ms (0.3 cycles) TOTAL TI ME 52.7ms OR 3.16 CYCLES Figure 78: SEL-387 Differential Minimum Trip Time 85 The Relay Testing Handbook Perform a timing test using the following steps: 1. Connect the test-set input(s) to the relay output(s) that are programmed to operate when the restrained-differential relay operates. 2. Configure your test-set to start a timer when current is applied and stop the timer and output channels when the appropriate input(s) operate(s). 3. Choose a connection diagram from Figures 72-74. Set a single-phase current at least 10% higher than the section Minimum Pickup setting using (the calculations in the “1-Phase Pickup 0.723 × 1.1 = 0.795A ) for Winding-1 or Test Procedure” of this chapter. (0.795A 2.634A (2.395 × 1.1 = 2.634A ) for Winding-2) 4. Run the test plan on the first phase related to restrained -differential. Record the test results. 5. Repeat the test on all phases related to the restrained-differential. RESTRAINED DIFFERENTIAL TIMING TESTS (cycles) WINDING TEST W1 0.723 A W2 2.634A W3 NA A PHASE (cy) BPHASE(cy) CPHASE(cy) 2 .4 1 0 2.45 NA 2.490 2.44 NA 2 .5 0 0 2 .4 8 NA MFG(cycles) 3.16 O3.16 K OK %ERROR OK OK O K OK NA 6. 3-Phase Restrained-Differential Slope Testing Differential slope testing is one of the most complex relay tests that can be performed and requires careful planning; a good understanding of the differential relay’s operating fundamentals; and information from the manufacturer regarding the relay’s characteristics. This section will discuss 3-Phase testing that will require at least six current channels to be performed correctly. Refer to the “1-Phase Restrained-Differential Slope Testing” section of this chapter if your test equipment has less than six-channels. Six-channel restrained-differential testing is actually ver y similar to the simple testing discussed in the previous chapter after the phase-angles between windings have been applied correctly. Six-phase restrained-differential testing is achieved by applying 3-phase balanced currents in each winding, mimicking an ideal-world steady state scenario, and then increasing all three currents in one winding simultaneously until the relay operates. The math is also simplified when you apply balanced three-phase conditions. 86 Chapter 2: Percent Dif ferential (87) Element Testing We discussed how to interpret the phase-angle-shift settings previously in this chapter which can be summarized by the following figure. BECKWITH ELECTRIC CONNECTION A C a C b a B c b A a c C B b A B A W1CTC=12 W2CTC=12 TRCON=YY CTCON=YY Transformer Connection 10. DACDACyy W1CTC=0 W2CTC=0 TRCON=DACDAC CTCON=YY Transformer Connection 04. DABYyy W1CTC=0 W2CTC=1 TRCON=DABY CTCON=YY Transformer Connection 02. YDACyy W1CTC=12 W2CTC=1 TRCON=YDAC CTCON=YY Transformer Connection 05. DACYyy W1CTC=0 W2CTC=11 TRCON=DACY CTCON=YY Transformer Connection 03. YDAByy W1CTC=12 W2CTC=11 TRCON=YDAB b a b C 01. Yyyy a c C SEL 587 Transformer Connection B c A SEL 387 M 3310 B c a A b C B c CTCON=YY Figure 79: Common Phase-Angle Compensation Settings 87 The Relay Testing Handbook Let’s figure out the test-settings for balanced full-load conditions for each case. The full load condition for Winding-1 is the Tap1 setting. All three-phases for Winding-1 should start at Tap1. All three-phases for Winding-2 should start at Tap2. The first case is SEL-387 when both W1CTC and W2CTC=12. Both settings are the same so there is no phase-angle shift for this connection. The Capital “A” (Winding-1) and lower case “a” (Winding-2) are both at 0º so our A-Phase test conditions will be at 0º. The other two phases will be 120º apart to create a three-phase balanced condition. A-Phase for Winding-2 will start at 180º to be opposite Winding-1 and the other two phases will be 120º apart as shown in the following table. CONNECTION A C a B c b SEL 387 W1AØ W1BØ W1CØ W2AØ W2BØ W2CØ W1CTC=12 W2CTC=12 Tap1@ 0º Tap1@ -120º Tap1@ 120º Tap2@ 180º Tap2@ 60º Tap2@ W2BØ = TAP2@60º W1CØ = TAP1@120º W2AØ = TAP2@180º 1 0 5 0 90 60 12 3 2 1 W1AØ = TAP1@0º 0 180 0 0 3 240 3 0 00 270 3 W1BØ = T AP1@-120º W2CØ = TAP2@-60º Figure 80: Yy12 or Yy0 3-Phase Differential Restraint Test Connections 88 -60º Chapter 2: Percent Dif ferential (87) Element Testing The next case is SEL-387 when both W1CTC and W2CTC=0. Both settings are the same so there is no phase-angle shift for this connection. The Capital “A” (Winding-1) and lower case “a” (Winding-2) are both at 0º so our A-Phase test conditions will be at 0º. The other two phases will be 120º apart to create a three-phase balanced condition. A-Phase for Winding-2 will start at 180º to be opposite Winding-1 and the other two phases will be 120º apart as shown in the following table. CONNECTION A C a B c b SEL 387 W1AØ W1BØ W1CØ W2AØ W2BØ W2CØ W1CTC=0 W2CTC=0 Tap1@ 0º Tap1@ -120º Tap1@ 120º Tap2@ 180º Tap2@ 60º Tap2@ -60º W2BØ = TAP2@60º W1CØ = TAP1@120º 0 12 W2AØ = TAP2@180º 1 90 60 2 1 W1AØ = TAP1@0º 3 0 0 5 180 0 0 24 0 270 3 00 3 3 0 W1BØ = TAP1@-120º W2CØ = TAP2@-60º Figure 81: Dd0 3-Phase Differential Restraint Test Connections 89 The Relay Testing Handbook The next case is SEL-387 with W1CTC=0 and W2CTC =1. The Capital “A” (Winding-1) is at 0º so our A-Phase test conditions will be at 0º. The other two phases will be 120º apart to create a three-phase balanced condition. The lower case “a” is at -30º so there is a phase shift between windings. Remember that we apply Winding-2 current 180º out-of-phase so the A-Phase for ° + 180 ° Winding-2 will start at 150º ( −30 ) to be opposite Winding-1. The other two phases will be 120º apart as shown in the following table. CONNECTION A a c C B b SEL 387 W1AØ W1BØ W1CØ W2AØ W2BØ W2CØ W1CTC=0 W2CTC=1 Tap1@ 0º Tap1@ -120º Tap1@ 120º Tap2@ 150º Tap2@ 30º Tap2@ W2AØ=TAP2@150º W1CØ = TAP1@120º 0 12 1 90 0 60 0 24 W2BØ =TAP2@30º 3 0 0 5 180 2 1 -90º 0 00 270 3 3 0 3 W1AØ = TAP1@0º W1BØ = TAP1@-120º W2CØ = TAP2@-90º Figure 82: Dy1 3-Phase Differential Restraint Test Connections The next case is SEL-387 with W1CTC=12 and W2CTC =1. The Capital “A” (Winding-1) is at 0º so our A-Phase test conditions will be at 0º. The other two phases will be 120º apart to create a three-phase balanced condition. The lower case “a” is at -30º so there is a phase shift between windings. Remember that we apply Winding-2 current 180º out-of-phase so the A-Phase for ° + 180 ° Winding-2 will start at 150º ( −30 ) to be opposite Winding-1. The other two phases will be 120º apart as shown in the following table. CONNECTION A c C B b 90 SEL 387 W1AØ W1BØ W1CØ W2AØ W2BØ W2CØ W1CTC=12 W2CTC=1 Tap1@ 0º Tap1@ -120º Tap1@ 120º Tap2@ 150º Tap2@ 30º Tap2@ a -90º Chapter 2: Percent Dif ferential (87) Element Testing W2AØ=TAP2@150º W1CØ = TAP1@120º 5 1 0 12 0 90 60 3 0 180 2 1 0 W1AØ = TAP1@0º 0 24 0 W2BØ=TAP2@30º 00 270 3 3 3 0 W1BØ = TAP1@-120º W2CØ = TAP2@-90º Figure 83: Yd1 3-Phase Differential Restraint Test Connections The next case is SEL-387 with W1CTC=0 and W2CTC =11 The Capital “A” (Winding-1) is at 0º so our A-Phase test conditions will be at 0º. The other two phases will be 120º apart to create a three-phase balanced condition. The lower case “a” is at 30º so there is a phase shift between windings. Remember that we apply Winding-2 current 180º out-of-phase so the A-Phase for Winding-2 will start at 210º (-150º) (30° + 180 ° ) to be opposite Winding-1. The other two phases will be 120º apart as shown in the following table. CONNECTION A b C SEL 387 W1AØ W1BØ W1CØ W2AØ W2BØ W2CØ W1CTC=0 W2CTC=11 Tap1@ 0º Tap1@ -120º Tap1@ 120º Tap2@ -150º Tap2@ 90º Tap2@ -30º a B c W2BØ = TAP2@90º W1CØ = TAP1@120º 5 1 0 0 90 60 12 3 180 2 W2AØ = TAP2@-150º 1 0 0 0 24 0 00 270 3 3 0 3 W1BØ = TAP1@-120º W1AØ = TAP1@0º W2CØ = TAP2@-30º Figure 84: Dy11 3-Phase Differential Restraint Test Connections 91 The Relay Testing Handbook The next case is SEL-387 with W1CTC=12 and W2CTC =11 The Capital “A” (Winding-1) is at 0º so our A-Phase test conditions will be at 0º. The othertwo phases will be 120º apart to create a three-phase balanced condition. The lower case “a” is at 30º so there is a phase shift between windings. Remember that we apply Winding-2 current 180º out-of-phase so the A-Phase for Winding-2 will start at 210º (-150º) (30° + 180 ° ) to be opposite Winding-1. The other two phases will be 120º apart as shown in the following table. CONNECTION A b C SEL 387 W1AØ W1BØ W1CØ W2AØ W2BØ W2CØ W1CTC=12 W2CTC=11 Tap1@ 0º Tap1@ -120º Tap1@ 120º Tap2@ -150º Tap2@ 90º Tap2@ a B c W2BØ = TAP2@90º W1CØ = TAP1@120º 5 1 0 0 90 60 12 3 0 180 2 W2AØ = TAP2@-150º 1 0 0 24 0 00 270 3 3 0 3 W1BØ = TAP1@-120º W1AØ = TAP1@0º W2CØ = TAP2@-30º Figure 85: Yd11 3-Phase Differential Restraint Test Connections 92 -30º Chapter 2: Percent Dif ferential (87) Element Testing A) Test-Set Connections The connection diagram for the SEL-387 is as follows: Figure 86: Schweitzer Electric SEL-387 Transformer Protective Relay Connections Follow the AØ primary buss through the Phase A CTs then follow the CT secondary to terminal Z01(IAW1). This is where we will connect the first current from our test-set. Connect the neutral of the test-set current channel to Z02 by following the other side of the CT to its relay terminal. Keep following the primary buss through the transformer to the Phase A' CT and then follow the secondary to terminal Z08. This is the neutral of the CTs so we will connect the test-set’s second current-channel-neutral-terminal to Z08. Follow the other side of the CT to terminal Z07 (IAW2) which is where we will connect the second channel current from the test-set. Follow the other phases to determine the following connections when testing B or Cphases. 93 The Relay Testing Handbook The test-set connections for a 3-Phase Restrained-Differential Slope test are displayed in the next figure. S E L - 38R 7 E L AY WINDING 1 Z01 + IAW1 Z02 IBW1 Z03 ICW1 Z06 WINDING 2 Z07 IAW2 Z08 ICW2 + + + + Z04 Z05 IBW2 R EL AY T ES T SE T + Z09 Phase A n gl e Frequency C1 Amps W1AØT estAmps C2 Amps W1BØ Test Amps -120° (240°) Test Hz C3 Amps W1CØT estAmps 120° TestHz 0° Test Hz (PS = Phase Shift) + + + + + + Z10 Z11 M a g n i t ud e Z12 C4 Amps W2AØ Test Amps W2AØ Test° TestHz C5 Amps W2BØT est Amps W2BØ Test° TestHz C6 Amps W2CØ Test Amps W2CØ Test° TestHz Alternate Timer Connection DC Supply + Element Output + + Timer Input Element Output + Timer Input Figure 87: 3-Phase Restrained-Differential Slope Test-Set Connections B) Pre-TestCalculations There severala significant different methods tocalculations test the restrained-differential Theelement first methodare involves amount of to determine exactlyslope. how the is supposed to operate, what test points will work best, and what results to expect. This section will discuss this method in detail. Remember that thereis an easier way that will be discussed later in this chapter. 94 Chapter 2: Percent Dif ferential (87) Element Testing The following information details the example test settings and expected characteristic curve. WIN D IN G 1 t n e r r u C e t a r e WIN D IN G 2 W_CTC 12 1 Tap_ 2.41 4.61 O87P 0.30 SLP1 20 SLP2 60 IRS1 3.0 P A T )x p Io ( p O Figure 88: Percentage Differential Protection Dual Slope Characteristic Curve 95 The Relay Testing Handbook We first need to change the restraint and operate current values to amps instead of multiples of Tap. Then we can calculate thetransition point between the Minimum Pickup and Slope-1 operation. The Winding-1 Minimum Pickup is 0.723A 0.3 ( × TAP1 ) as we calculated earlier in this chapter. Slope-1 will start operating when the operate current is greater than the minimum pickup. Different relays have different slope calculations and we can refer to the SEL-387 relay instruction manual to determine the relay’s differential calculation as shown in Figures 89 and 90. Method: Decide to is cross the differential by picking a restraintwhere valueyou IRT,want which a vertical line on thecharacteristic graph. Because this test is for the SLP1 threshold, select a point above the O87P intersection point and below IRS1. If SLP2 = OFF, IRS1 and SLP2 are not functional. O87P • 100 SLP1 < IRT < IRS1 The value of IOP corresponding to the selected IRT equals the following: IOP = SLP1 100 • IRT Both IRT and IOP are in multiples of tap. Figure 89: SEL-387 Slope-1 Differential Formulas The resulting A-phase, B-phase, and C-phase currents from each winding then go to the differential elements -2, and -3, respectively. each element aofphasor addition sums the winding currents. The87R-1, magnitude of this result is IOP.In The magnitudes the winding currents are then summed in a simple scalar addition and divided by two. This result is IRT. For example, for a balanced through-load current of 4 amps, these calculations produce ideal results of IOP = 0 and IRT = 4. Figure 90: SEL-387 Definition of IOP and IRT 96 Chapter 2: Percent Dif ferential (87) Element Testing Notice that the IRT current is defined as “The magnitudes of the winding currents are then summed in a simple scalar addition and divided by 2.” This can be translated into I +I because we will use balanced 3-phase currents atthe theoretical normal operating 2 angles. The IOP currentis defined as “In each element a phasor addition sums the winding currents.” The magnitude of this result is IOP which can be translated intoIW1 − IW 2 for our calculations because we will use balanced 3-phase currents at the theoretical normal operating angles. Remember that both of these formulas are still in per-unit and not actual Amp values. W1 W2 Use the first IOP formula to calculate the transition We should calculate the expected Winding-1 between Minimum Pickup and Slope-1. current for a Winding-2 current less than6.915A. O87P × 0.3 × 100 IRS1 The value of IOP that corresponds to the selected IRT is as follows: IOP = SLP2 • +IRT• IRS1  SLP1 − SLP2  100 100   Both IRT and IOP are in multiples of tap. Figure 91: SEL-387 Slope-2 Differential Formulas −  SLP2     SLP1 SLP2 IOP =  × +IRT ×  IRS1   100  100        0.7IW1 +1.2 =1.3 IW 2  60     IOP =  × + IRT ×   3.0 100        20 60−  100 1.3IW 2 −1.2 0.7   −40   IOP = 0.6IRT + 3.0 ×    100    IW 1 = IOP = 0.6IRT + IW1 = 1.3IW 2 − 1.2 0.7 0.7 −× 3.0 0.40  IOP = 0.6IRT + −1.2  IW 1 − IW=2 × 0.6 IW 1 = 1.857IW 2 − 1.714  IW 1 + IW 2  − 1.2 2 IW 1 − IW+2 = 1.2 × 0.6  IW 1 + IW 2  2 IWI1W2−  + = ×1.2 IWI0.3 + 1W2 IWIW − + =1.2 I W1 +0.3 I W2 12  0.3 IW 1 −I0.3 IWI2W+20 .3 W1 + = 1.2 0.7IW1 +1.2 =1.3 IW 2 100 0.7IW 1 =1.3 IW 2 −1.2 0.7IW1 +1.2 =1.3 IW 2 IW 2 = 0.7IW 1 +1.2 1.3 IW 2 = 0.7IW1 1.2 + 1.3 1.3 IW 2 = 0.538IW1 + 0.923 Chapter 2: Percent Dif ferential (87) Element Testing Remember that the calculations so far are in per-unit. The following calculations change the per-unit to actual current applied. IW1 = 1.857I W2 W2 = 0.538W1 + 0.923 −1.714 IAW2 I = 0.538 AW1 + 0.923 TAP2 TAP1 IAW1 I = 1.857 × AW2 −1.714 TAP1 TAP2 IAW1 2.41 IAW2 I = 1.857 × AW2 −1.714 4.61 = 0.538 4.61 I AW1 + 0.923 2.41 IAW1 = 0.403IAW2 − 1.714 2.41 IAW2 = 0.223IAW1 + 0.923 4.61 IAW1 = (0.403IAW2 −1.714 ) ×2.41 IAW2 = (0.223IAW1 +0.923 ) ×4.61 IAW1 = (0.403IAW2 × (− 2.41 ) × ) 1.714 IAW2 = (0.223IAW1 × (+ 4.61 ) × 2.41 ) 0.923 4.61 IAW2 = 1.029IAW1 +4.255 IAW1 = 0.971IAW2 −4.131 The actual characteristic curve of this 87-Element using Winding-1 and Winding-2 currents can be plotted where W2 (Restraint Current) is a group of arbitrary numbers and W1 (Operate Current) uses the following formulas: • I • • • I If ( AW 2 < 6.915A I then If ( AW 2 > 6.915A and <12.406A) I then I AW1 If (I AW > 12.406A) then I AW1 = 0.723 I +0.523 =0.971I 2 AW2 AW1 AW 2 = 0.639 AW 2 −4.131 The spreadsheet calculation for these equations could be: EXPECTED <=I IF(+ AW 2 6.915,0 .723 < (0.523* II IF 22 ), AW ( 2 IAW − 2 12.406,0 .639* I ,(0.971* AW ) 4.131)) AW Differential Protection Characteristic Curve 25.00 Trip Area 20.00 t n e rr u C te a r e p O ) s p 15.00 m A in 1 Slope 2 10.00 Slope 1 W (I 5.00 0.00 O87P Restraint Area 0 1 2 3 4 5 6 7 8 9 10111 2131 4151 6171 819 20212 2232 4252 6 Restraint Current (I W2 in Amps) Figure 92: Percentage Differential Protection Dual Slope Characteristic Curve in Amps 101 The Relay Testing Handbook You could use this graph to determine the expected pickup current for a Slope-1 test by choosing a W2 current after the Minimum Pickup and less than Slope-2. Find that current on the x-axis, follow the current up until it crosses the line, then follow the crossover point back to the other axis to determine the expected pickup. For example, we could test Slope-1 by applying 2xTap to both windings and increase the W1 current until the relay operates. The relay should operate at approximately 5.9A as shown in Figure 93. Test Slope-2 by choosing a current below the Slope-2 portion of the graph (4xTap=18.44A), follow 18.44A from the x-axis to the characteristic curve, and follow it to the y-axis. The expected pickup current for the Slope-2 test is 13.7A as per Figure 93. Differential Protection Characteristic Curve 25.00 Trip Area 20.00 t n e rr u C e t ra e p O )s p m A n i 1 Slope 2 15.00 10.00 Slope 1 I( W Restraint Area 5.00 0.00 0 1 2 3 4 5 6 7 8 9 101 11 21 31 41 51 61 71 81 92 02 12 22 32 42 52 6 Restraint Current (I in Amps) W2 Figure 93: Using Graphs to Determine Pickup Settings It is more convenient to use formulas to determine the expected pickup current as shown below. SLOPE 1 SLOPE 2 IAW1 = 0.971IAW2 −4.131 I AW1 = 0.639I AW 2 IAW1 = 0.971 (18.44A ) −4.131 I AW1 = 0.639 (9.22A ) IAW1 = 17.905A −4.131 I AW1 = 5.892A 102 IAW1 = 13.774A Chapter 2: Percent Dif ferential (87) Element Testing The test sheet for this test could be similar to the test sheet below with the “EXPECTED” calculation: EXPECTED <=I IF(+ AW2 < 6.915,0.723 (0.523* II IF22 ), AW ( 2 AW I− 2 12.406,0.639* I ,(0.971* AW ) 4.131)) AW DIFFERENTIAL TEST RESULTS TEST PICK UP SLOPE 1 0.3 20% SLOPE 2 60% IAW2 (A) 1 10.0 A 2 12.0 A 3 16.0 A 4 18.0 0 2.41 TIME DELAY TAP1 TAP2 4.61 SLOPE TESTS (Amps) I_W1 PHASE (A) 12 W2CTC 1 EXPECTED(A) 6.401 7.69 11.421 13.368 A W1CTC %ERROR 6.390 0.17 7.668 0.29 11.405 0.14 13.347 0.16 C) Post-Test Calculations It is often easier to pick random points and perform a calculation to determine if the test result is correct rather than perform all of the calculations above. We’re using the same information for this test as summarized below: WI N D IN G 1 WI N D IN G 2 W_CTC 12 1 Tap_ 2.41 4.61 O87P 0.30 SLP1 20 SLP2 60 IRS1 3.0 103 The Relay Testing Handbook IRT is defined as “The magnitudes of the winding currents are then summed in a simple scalar addition and divided by 2.” This can be translated intoIW1 + IW 2 because we will 2 use balanced 3-phase currents at the theoretical normal operating angles. IOP is defined as “In each element a phasor addition sums the winding currents. The magnitude of this result is IOP which can be translated intoIW1 − IW 2 for our calculations because we will use balanced 3-phase currents at the theoretical normal operating angles. Remember that both of these formulas are still in per-unit and not actual Amp values. O87P SLP1 SLP2  SLP2  IOP =  × +IRT  100  O87P × 0.3 × 100 3=Slope-2 −  SLP2     SLP1 SLP2 IOP =  × +IRT ×  IRS1   100  100     SLP1 IOP = ×IRT 100 IOP SLP1 = IRT 100  SLP2  IOP =  ×IRT  1.2 −  100  SLP1 = 100 × IOP IOP +1.2 =  SLP2 × IRT   100  IRT Test6 SLP1=100 × IOP IRT Test6 SLP1=100 × 0.487 2.413 IOP + 1.2 SLP2 = IRT 100 SLP2 = 100 × IOP + 1.2 IRT Test6 SLP1=20.18% Test10 SLP2 = 100 × Test7 SLP1=100 × 0.588 2.897 Test10 SLP2 = 100 × Test7 SLP1=20.30% IOP + 1.2 IRT 1.642 + 1.2 4.726 Test10 SLP2 = 60.13% The final test sheet could look like the following: DIFFERENTIAL TEST RESULTS PICK UP 0.3 SLOPE 1 20% TAP1 2.41 W1CTC 12 60% TAP2 4.61 W2CTC 1 SLOPE 2 TIME DELAY 0 PICKUP TESTS TEST 106 IRT IOP EXPECTED ACTUAL 1 IAW2 (A) 0.0 A IAW1 (A) 0. 726 0 .15 1 0.3 01 0.30 0.30 0.41 2 2.0 A 1. 779 0 .58 6 0.3 04 0.30 0.30 1.44 3 4.0 A 2. 825 1 .02 0 0.3 05 0.30 0.30 1.51 4 6.0 A 3. 878 1 .45 5 0.3 08 0.30 0.31 2.54 5 8.0 A 5. 128 1 .93 2 0.3 92 20.00 20.32 1.59 6 10.0 A 6. 401 2 .41 3 0.4 87 20.00 20.18 0.89 7 12.0 A 7 .69 2 .89 7 0.5 88 20.00 20.29 1.46 8 14.0 A 9 .47 3 .48 3 0.8 93 60.00 60.08 0.13 9 16.0 A 11. 421 4 .105 1.2 68 60.00 60.13 0.22 10 18.0 A 13. 368 4 .72 6 1.6 42 60.00 60.15 0.24 11 20.0 A 15. 309 5 .34 5 2.0 14 60.00 60.13 0.21 12 13 22.0 A 24.0 A 17 .25 19. 197 5 .96 5 6 .58 6 2.3 85 2.7 59 60.00 60.00 60.11 60.12 0.18 0.20 14 26.0 A 21. 143 7 .20 6 3.1 33 60.00 60.13 0.21 15 28.0 A 23.091 7.828 3.508 60.00 60.14 0.24 ERROR (%)    Chapter 2: Percent Dif ferential (87) Element Testing The formulas used for this test report are: • • • • IRT=((IAW2 / TAP2) + (IAW1 / TAP1)) / 2 IOP=(IAW1/TAP1)-(IAW2/TAP2) EXPECTED=IF(IRT<(O87P ×100 / SLP1),O87P,IF(IRT<3,SLP1,SLP2)) ACTUAL=IF(IRT<(O87P ×100 / SLP1),IOP,IF(IRT<3,100*(IOP/IRT),100*((IOP+1.2)/IRT))) D) Alternate Slope Calculation There is another way to test slope that does not require as much preparation or calculation. Follow the Post-Test Calculation in the previous section to the point that IRT and IOP are calculated and pick two test points from each slope. You can tell which test will be Slope-1 if the IRT is between 1.5 and 3. Slope-2 will occur if the IRT is greater than 3. DIFFERENTIAL TEST RESULTS PICK UP 0.3 SLOPE 1 20% TIME DELAY TAP1 2.41 W1CTC 12 SLOPE 2 60% TAP2 4.61 W2CTC 1 0 PICKUP TESTS TEST IAW2 (A) 6 10.0 A IAW1 (A) 6 .4 0 1 IRT IOP 2 . 4 13 0 .4 8 7 7 12.0 A 7.69 2 . 8 97 0 .5 8 8 10 18.0 A 1 3. 3 6 8 4 . 7 26 1 .6 4 2 11 20.0 A 15.309 5 . 3 45 2 .0 1 4 EXPECTED ACTUAL ERROR (%) You can use the graphical Rise over Run formula to determine the slope if you know the correct IOP and IRT for any two test results for a given slope as shown in the following example. Differential Protection Characteristic Curve Trip Area 20 t n e rr u C e t a r e p O ) s p Slope 2 m A in 1 W (I Rise2 Run2 10 Slope 1 Run1 Rise1 Restraint Area 0 0 10 20 30 Restraint Current W2 (I in Amps) Figure 94: Determine Slope by Rise/Run Calculation 107 The Relay Testing Handbook Determine slope using the rise-over-run graphical method as shown in Figure 94 and the following formulas: %Slope1 = 100 × %Slope2 = 100 × IOP7 - IOP6 IRT7 - IRT6 %Slope2 = 100 × 0.588 - 0.487 %Slope2 = 100 × %Slope1 = 100 × %Slope1 = 100 × Rise Run 2.897 - 2.413 %Slope1 = 100 × Rise Run IOP11- IOP10 IRT11- IRT10 2.014 - 1.642 5.345 - 4.726 0.101 0.484 %Slope2 = 100 × %Slope1 = 20.86% 0.372 0.619 %Slope2 = 60.09% The final test sheet could look like the following: DIFFERENTIAL TEST RESULTS PICK UP 0.3 SLOPE 1 20% TIME DELAY TAP1 2.41 W1CTC 12 SLOPE 2 60% TAP2 4.61 W2CTC 1 0 PICKUP TESTS TEST IAW2 (A) 6 10.0 A IAW1 (A) IRT IOP 6.401 2 . 41 3 0.487 7 12.0 A 7.69 2 . 89 7 0.588 10 18.0 A 1 3 . 3 68 4 . 72 6 1.642 11 20.0 A 1 5 . 3 09 5 . 34 5 2.014 EXPECTED ACTUAL 20.00 20.86 4.28 60.00 59.97 -0.06 ERROR (%) E) 3-Phase Differential Slope Test Procedure The slope test procedure seems straightforward. Apply 3-phase balanced current into Winding-1 and Winding-2 using the phase shift described in the previous section of this chapter, and raise all three currents in one winding until the relay operates. The difficult part of this procedure is determining what starting current to apply and what the expected pickup should be. You can use one of the following test procedures to test the relay slope settings: • Pre-Test Calculations—Use the calculations to determine the actual restraint • and expected operate currents and insert these values into the procedure. Post-Test Calculations—Start at 0.00A restraint current and determine pickup. Increase the restraint current and determine pickup and repeat until the O87P, Slope-1, and Slope-2 settings are tested. Calculate IRT after each test to determine whether O87P, Slope-1, or Slope-2. 108 Chapter 2: Percent Dif ferential (87) Element Testing Follow these steps to test the Differential Slope settings using six current channels: 1. Determine how you will monitor pickup and set the relay accordingly, if required. (Pickup indication by LED, output contact, front panel display, etc…See previous packages of The Relay Testing Handbookfor details.) 2. Determine the Slope-1 restraint current by selecting a value between the Minimum- Pickup and Slope-2 transition points. Apply balanced, 3-phase restraint current through W2 at the phase-angle described in the “3-Phase Restrained-Differential Slope Testing” chapter of this chapter. The pickup indication should be ON because we have applied a 200% slope as per the calculations earlier in this document. The applied W2 current for our example will be: CONNECTION A W1AØ W1BØ W1CØ W2AØ W2BØ W2CØ W1CTC=12 W2CTC=1 0A 0º 0A -120º 0A 120º 10.0A@ 150º 10.0A@ 30º 10.0A@ a c C SEL 387 B -90º b 3. We are applying current greater than 5.0A into the relay so this test should be completed as quickly as possible. You may want to apply the previous step fora moment to ensure the 87-Element operates and setup the next step offline. 4. Apply an equal, but opposite (accounting for phase shift) 3-Phase current in W1. You can use the Tap ratios to determine what the current should be. For example: W1 = W2 × W1 = 10 × TAP1 TAP2 2.41 4.61 W1 = 10 × 0.523 W1 = 5.23 CONNECTION A W1AØ W1BØ W1CØ W2AØ W2BØ W2CØ W1CTC=12 W2CTC=1 5.23A 0º 5.23A -120º 5.23A 120º 10.0A@ 150º 10.0A@ 30º 10.0A@ a c C SEL 387 B -90º b The Relay should not operate. 109 The Relay Testing Handbook 5. Raise the W1 current until the element operates. Because the applied current ishigher than 10.0A, you could also use the pulse or jog method to minimize the amount of current applied to the relay. (Review the Instantaneous Overcurrent (50-Element) pickup procedure in previous packages ofThe Relay Testing Handbookfor details.) The measured pickup for our example is 6.401A. 6. Some organizations want more than one test point to determine slope. Repeat steps 2-5 with another restraint current between the Minimum-Pickup and Slope-2 transition points until the required number of tests are completed. 7. Test Slope-2 by repeating steps 2-6 with a restraint current greater than the Slope-1 to Slope-2 transition level. 8. Compare the pickup test result to the manufacturer’s specifications and calculate the percent error as shown in the following example. DIFFERENTIAL TEST RESULTS TEST PICK UP 0.3 SLOPE 1 20% TAP1 SLOPE 2 60% TAP2 IAW2 (A) 1 10.0 A 2 12.0 A 3 16.0 A 4 18.0 A TIME DELAY 0 2.41 W1CTC 12 4.61 SLOPE TESTS (Amps) W2CTC 1 I_W1 PHASE (A) 6.401 7.69 11.421 13.368 EXPECTED(A) %ERROR 6.390 0.17 7.668 0.29 11.405 0.14 13.347 0.16 Slope-1 In the TEST 1 example, we calculated that the 87-Element should operate when IAW1 = 6.390A using the Slope-1 formula when IAW2 = 10.0A. We measured the pickup to be 6.175A. Looking at the “Differential Element” specification below, we see that the acceptable metering error is ±0.5% ± 0.1A . All of the results in the test sheet are less than 0.5% so we can consider them acceptable. Differential Element 110 Unrestrained Pickup Range: 1–20 in per unit of tap Restrained Pickup Range: 0.1–1.0 in per unit of tap Pickup Accuracy (A secondary) 5 A Model: 1 A Model: ±5% ±0.10 A ±5% ±0.02 A Chapter 2: Percent Dif ferential (87) Element Testing IAW1-EXPECTED × 100 = Percent Error EXPECTED 6.401-6.390 × 100 = Percent Error 6.390 0.17% Allowable Percent Error We can calculate the manufacturer’s allowable percent error. Using “ 0.5% ± ±0.1 A ” from the specifications above, the allowable percent error is 1.6%. Maximum Accuracy Tolerance × 100 = Allowable Percent Error Expected (0.5% ×EXP ECTED ) + 0.1A Expected (0.005 × 6.39A ) + 0.1A 6.39A (0.032) + 0.1A 6.39A × 100 = Allowable Percent Error × 100 = Allowable Percent Error × 100 = Allowable Perce nt Error 0.132 × 100 = Allowable Percent Error 6.39A 2.1% Allowable Percent Error Rule of Thumb Remember that there are other factors that will affect the test result such as: • • • Relay close time. (The longer it takes the contact to close the larger the test result will be if ramping the pickup current.) Test-set analog output error. Test-set sensing time. Some of these error factors can be significant and a rule-of-thumb 5% error is usually applied to test results. 9. Repeat the pickup test for all windings that are part of the differential scheme. If more than two windings are used, change all connections and references to W2 to the next winding under test. (W2 becomes W3 for W1-to-W3 tests) 111 The Relay Testing Handbook 7. 1-Phase Restrained-Differential Slope Testing 3-Phase differential slope testing is relatively straight-forward as you simulate balanced 3-phase conditions that the relay would expect to see in an ideal world to make all of the calculations easier. The 1-Phase testing procedure described in this section uses the same calculations and test procedure described in the previous “3-phase Differential Slope Testing” section but the connections are completely different. Schweitzer Engineering Laboratories does have a test procedure and calculation for single-phase testing but I have found that the procedure described here is easier to apply and calculate. Our example will use the same settings used earlier in this chapter for the SEL-387 which are summarized to: W I N DI N G 1 Y Y 12 230 2.41 0.30 20 60 3.0 E87W_ W_CT W_CTC VWDG_ Tap_ O87P SLP1 SLP2 IRS1 WI N D IN G 2 Y Y 1 18 4.61 A) Understanding theTest-Set Connections Wye-Wye and Delta-Delta connections are not a problem as there is no phase shift and the current in any phase-winding is reflected in the same phases on the other windings. However in a Delta-Wye or Wye-Delta transformer, the current in one Wye phase CT is reflected into two phases of the Delta CT as shown in Figure 95. CT1 CT2 400:5 H1 PHA IH1=0º 1200:5 IA @ º 0 @ a I IB @ -1 2 0 º º 0 2 -1 I C @ 1 2 0 º º 0 2 1 @ Ic 0 º H2 X1 IX1=Ia-Ic@-30º X2 PHB IH2@-120º H3 PHC @ Ib IH3@120º IX2@-150º X3 IX3@90º H0 Figure 95: YDac Transformer Connection When testing transformer differential elements on a single-phase basis, we must apply the W1 current to the phases W2 usually measures. Then apply the W2 current to the phases 112 Chapter 2: Percent Dif ferential (87) Element Testing W1 normally measures. For the example in Figure 95, connect the W1 test current to IAW1 and ICW1 in series and the W2 test current is applied to IAW2 for an A-Phase test. Connect the B-Phase W1 test current to IBW1 and IAW1 and W2 test current to IBW2. Connect the C-Phase W1 test current to ICW1 and ICW1 and W2 test current to ICW2. Another problem with 1-Phase testing is the unbalance or zero sequence current that is applied to the relay. Zero-sequence is a problem in transformer differential protection because a phase-to-ground fault outside the transformer on the power system can cause zero-sequence current to flow through one winding of the transformer and not appear in the other winding due to a delta or tertiary winding. Most digital relays apply zerosequence filtering to prevent a transformer differential trip for ground faults on the power system. Zero-sequence filtering is applied on the SEL-387 relay when the W_CTC setting equals 12. A phase-to-phase connection is required to compensate for the zero-sequence compensation. When both W_CTC settings are equal, both windings will use a PhasePhase connection. Use the table in Figure 96 to determine the correct 1-Phase test connections. GE T-6 0 , T-3 0 S R-7 4 5 W1=0, W2=0 W1=0, W2=30° W1=0, W2=330° Y/y0° Y/d30° Y/d330° D/d0° D/d0° B e ckwit h S E L -5 8 7 Yyyy YDACyy YDAByy YY YDAC DACY S E L - 3 87 W1 W2 12 12 12 12 1 11 12 DACDACyy DACDAC 0 0 0 0 W1=0, W2=30° W1=0, W2=330° D/y30° D/y330° DABYyy DACyy DABY DACY 0 0 12 1 11 1 1 1 11 0 12 1 0 11 11 12 11 APha s e W1 W2 BP ha s e W1 W2 C - Ph a s e W1 W2 A-B A-B B-C B-C C-A C-A A-C A-N B-A B-N C-B C-N A-B A-N B-C B-N C-A C-N A-B A-B B-C B-C C-A C-A A-N A-N B-N B-N C-N C-N A-B A-B B-C B-C C-A C-A A-C A-N B-A B-N C-B C-N A-B A-N B-C B-N C-A C-N A-N A-C B-N B-A C-N C-B A-N A-C B-N B-A C-N C-B A-N A-N B-N B-N C-N C-N A-N A-B B-N B-C C-N C-A A-N A-N A-B A-N B-N B-N B-C B-N C-N C-N C-A C-N Figure 96: Transformer Relay Connections for Single-Phase Differential Testing 113 The Relay Testing Handbook B) Test-Set Connections The connection diagram for the SEL-387 is as follows: Figure 97: Schweitzer Electric SEL-387 Transformer Protective Relay Connections The winding settings for this transformer are W1CTC=12 and W2CTC=1. Using the table in Figure 96, the following test-set connections will be required for each phase: S E L- 38R 7E LA Y RE L AT YE SS TE T WINDING 1 Z01 IAW1 Z02 + + Z03 + + + + IBW1 ICW1 Z04 Z05 Z06 WINDING 2 Z07 IAW2 Z08 + Z09 + IBW2 ICW2 M a g n i t ud e P ha s eA ng le Frequency C1 Amps W1AØT estAmps 0° Test Hz C2 Amps W2AØ Test Amps 180° Test Hz C3 Amps 0.00A 0° Test Hz Z10 Z11 + Z12 Alternate Timer Connection + DC Supply - Element Output + + Timer Input Element Output + Timer Input Figure 98: 1-Phase Restrained-Differential Slope Test-Set AØ Yd1 Connections 114 Chapter 2: Percent Dif ferential (87) Element Testing S E L- 38R 7E LA Y RE L AT YE SS TE T WINDING 1 Z01 IAW1 Z02 + + Z03 + + + + IBW1 ICW1 Z04 Z05 Z06 WINDING 2 Z07 IAW2 Z08 Z09 IBW2 Z10 ICW2 Z11 M a g ni t u d e Pha se A ngle Frequency C1 Amps W1BØT estAmps 0° Test Hz C2 Amps W2BØ Test Amps 180° Test Hz C3 Amps 0.00A 0° Test Hz + + + Z12 Alternate Timer Connection + DC Supply - Element Output + + Timer Input - Element Output + Timer Input Figure 99: 1-Phase Restrained-Differential Slope Test-Set BØ Yd1 Connections S E L- 38R 7E LA Y RE L AT YE SS TE T WINDING 1 Z01 IAW1 Z02 + + Z03 + + Z04 Z05 + + IBW1 ICW1 M a g ni t u d e Z06 WINDING 2 Z07 IAW2 Z08 + Z09 + IBW2 ICW2 Pha se A ngle Frequency C1 Amps W1CØT estAmps 0° Test Hz C2 Amps W2CØ Test Amps 180° Test Hz C3 Amps 0.00A 0° Test Hz Z10 Z11 + Z12 Alternate Timer Connection + DC Supply - Element Output + + Timer Input Element Output + Timer Input Figure 100: 1-Phase Restrained-Differential Slope Test-Set CØ Yd1 Connections 115 The Relay Testing Handbook C) 1-Phase Differential SlopeTest Procedure Follow these steps to test the Differential Slope settings using the Post-Test Calculation method from the previous “3-Phase Differential Slope Testing” Section: 1. Determine how you will monitor pickup and set the relay accordingly, if required. (Pickup indication by LED, output contact, front panel display, etc…See previous packages of The Relay Testing Handbookfor details.) 2. Apply a restraint current into the first test phase of Winding-2. The pickup indication should be on. 3. Apply an equal, but opposite current in W1 using the Tap ratios to determine what the current magnitude should be. For example: W1 = W2 × W1 = 5 × TAP1 × A1 TAP2 × A2 2.41 × 1 4.61 × 1.732 W1 = 5 × 0.302 W1 = 1.510 4. The pickup indication should now be off. Raise the Winding-1 current until the relay operates. Record thetovalue on your sheet. (Remember yourelay. can Review also usethe the pulse or jog method minimize the test amount of cur rent appliedthat to the Instantaneous Overcurrent (50-Element) pickup procedure in previous packages of The Relay Testing Handbookfor details.) 5. Calculate the IRT, IOP, and Slope using the formulas in the Post-Test Calculation section of the “3-Phase Differential Slope Testing” in this document. Use a 1.732 correction factor for windings with odd W_CTC settings and use the IRT calculation to determine if the test was O87P, Slope-1, or Slope-2. Raise the W2 current and repeat 2-5 until all elements of the differential protection have been tested. ¾ ¾ IRT= (IAW2 / (TAP2 ×A2 / TAP1 ) ) + IAW1 ( ( A1 × ))/ 2   ×( A1 -) IAW2/  IOP= IAW1/ TAP2 ×A2 ( )TAP1 × ¾ EXPECTED=IF(IRT<(O87P 100 / SLP1),O87P,IF(IRT<3,SLP1,SLP2)) ¾ 116 ACTUAL=IF(IRT<(O87P ×100 / SLP1),IOP,IF(IRT<3,100*(IOP/IRT),100*((IOP+1.2)/IRT))) Chapter 2: Percent Dif ferential (87) Element Testing 6. Compare the pickup test result to the manufacturer’s specifications and calculate the percent error as shown in the following example. DIFFERENTIAL TEST RESULTS PICK UP 0.3 SLOPE 1 20% TIME DELAY TAP1 2.41 W1CTC 12 1 SLOPE 2 60% TAP2 4.61 W2CTC 1 1.732 0 CORR PICKUP TESTS TEST IAW2 (A) IAW1 (A) IRT IOP EXPECTED ACTUAL 0 .3 0 5 0.30 0.31 0 .3 0 3 0.30 0.30 0.94 0 .4 2 0 20.00 20.11 0.57 0 .5 6 3 20.00 20.21 1.06 0 .9 8 6 60.00 60.33 0.54 4 . 5 19 1 .5 2 3 60.00 60.26 IRT IOP EXPECTED ACTUAL 1 0.0 A 2 5.0 A 2.239 0 . 7 78 3 15.0 A 5. 5 4 2 . 0 89 4 20.0 A 7. 3 9 4 2 . 7 86 5 25.0 A 9.923 3 . 6 24 6 30.0 A 1 2. 7 2 6 TEST IAW2 (A) 0.736 IBW2 (A) 0 . 1 53 ERROR (%) 1.80 0.44 ERROR (%) 7 0.0 A 0.732 0 . 1 52 0 .3 0 4 0.30 0.30 1.24 8 5.0 A 2.24 0 . 7 78 0 .3 0 3 0.30 0.30 1.08 9 15.0 A 5. 5 4 4 2 . 0 90 0 .4 2 2 20.00 20.19 0.93 10 20.0 A 7. 3 8 2 2 . 7 84 0 .5 5 8 20.00 20.05 0.26 11 25.0 A 9.902 3 . 6 20 0 .9 7 8 60.00 60.16 0.26 12 30.0 A 1 2. 7 1 1 4 . 5 16 1 .5 1 7 60.00 60.17 IRT IOP EXPECTED ACTUAL TEST IAW2 (A) IBW2 (A) 0.28 ERROR (%) 13 0.0 A 0.732 0 . 1 52 0 .3 0 4 0.30 0.30 1.24 14 6.0 A 2.544 0 . 9 04 0 .3 0 4 0.30 0.30 1.38 15 16 15.0 A 21.0 A 5. 5 3 5 7. 7 5 3 2 . 0 88 2 . 9 24 20.00 20.00 20.02 20.08 0.12 0.38 17 24.0 A 9.342 3 . 4 41 0 .8 7 1 60.00 60.17 0.28 18 27.0 A 1 1. 0 3 5 3 . 9 80 1 .1 9 7 60.00 60.23 0.38 0 .4 1 8 0 .5 8 7 7. Repeat steps 2-6 for all three phases. 8. Repeat the pickup test for all windings that are part of the differential scheme. If more than two windings are used, change all connections and references to W2 to the next winding under test. (W2 becomes W3 for W1 to W3 tests) 117 The Relay Testing Handbook 8. Harmonic Restraint Testing Transformers are inductive machines that require a magnetic field to operate. Under normal operating conditions, there are very small losses inside the transformer that are typically less than 3%. A large inrush of current is required in the first few cycles after energization to create the magnetic field necessary for transformer operation. This current only occurs in the firstenergized winding and can be up to 10x the transformer’s nominal current that, in any other circumstance, would be the definition of transformer differential and the differential relay should operate. We do not want the transformer differential to operate every time a transformer is energized, and there are several options available to prevent transformer inrush from tripping the differential relay. It is possible to block the 87-Element for a preset time after a circuit breaker is closed, but an internal transformer fault would not be isolated until the time delay had passed that will cause additional damage for the extended time caused by this workaround. You could increase the pickup setting, but this would prevent the relay from operating during high-impedance faults. The most common technique used to prevent differential operation during inrush conditions is called Harmonic Restraint or Harmonic Blocking. Figure 101 displays a typical transformer inrush waveform. As you can see, this is not your typical sine wave. There is a significant DC offset in the first few cycles where the center point between the positive and negative peaks is not the x-axis. Also the waveform is extremely distorted and doesn’t display the nice round peaks we normally see. Figure 101: Transformer InrushWaveform 118 Chapter 2: Percent Dif ferential (87) Element Testing Protective relay designers analyzed these waveforms and realized that the distortion was caused by even harmonic content that typically only occurred during transformer energization and not during transformer faults. Harmonic detectors were built into transformer differential relays which measure the percent of 2nd,4th and/or 5th harmonics in a waveform. These harmonic detectors will prevent differential operation if the harmonics exceed a pre-defined setpoint. A) Harmonic Restraint Test Connections There are two possible connections for testing Harmonic Restraint depending on your test equipment. If your test equipment allows you to directly adjust the applied harmonic for an output current channel, you can use the standard timing test connections diagram shown in Figure 102. S E L - 3 8R 7 EL A Y R ELA Y T ES S TE T WINDING 1 Z01 IAW1 Z02 + + Z03 + + + + IBW1 ICW1 Z04 Z05 Z06 WINDING 2 Z07 IAW2 Z08 IBW2 ICW2 M a g n it ud e P ha s e A ng le Frequency C1 Amps W1AØT estAmps 0° Test Hz C2 Amps W1BØ Test Amps 0° Test Hz C3 Amps W1CØT 0° TestHz estAmps + Z09 Z10 + Z11 + Z12 Alternate Timer Connection + DC Supply - Element Output + + Timer Input Element Output + Timer Input Figure 102: Simple 3-Phase 87-Element Test-Set Connections 119 The Relay Testing Handbook Otherwise you will need two channels to test the Harmonic Restraint connect ed in parallel as shown in Figure 103. This test configuration includes one channel at the fundamental frequency and the second channel set at the harmonic frequency. The harmonic percentage is the ratio of harmonic current to fundamental current. S E L - 3 8R 7 E L AY WINDING 1 Z01 IAW1 Z02 IBW1 ICW1 R E LAY T E SS T ET Magnitude + + Z03 Z04 + + Z05 + + Z06 WINDING 2 Z07 IAW2 Z08 + Z09 + IBW2 ICW2 C1 Amps Phase Angle Frequency W1AØ Test Amps C2 Amps W1AØ Harmonic Amps C3 Amps 0.00A 0° Test Hz 0° HarmonicHz 0° TestHz Z10 Z11 + Z12 Alternate Timer Connection +DC Supply - Element Output + + Timer Input Element Output + Timer Input Figure 103: Simple, Higher Current 3-Phase 87-Element Test-Set Connections B) Harmonic RestraintTest Procedurewith Harmonics Harmonic Restraint application can be very different depending on the relay manufacturer and model. Some relays will only restrain when the current is pulsed to look like the sudden inrush of a transformer. Other relays may require the harmonic to start below the setting and ramp up. Some other relays may require the harmonic to be above the setpoint and ramp down so you actually measure thedropout instead of the pickup. We will modify our timing test procedure to apply the pulse method which should work on most relays. Use the following procedure to test the Harmonic Restraint when a harmonic setting is available on your test-set. 1. Turn the test-set channel harmonic setting on and choose the correct harmonic. (Typically the 2nd , 4th, or 5th Harmonic.) 2. Apply the connection diagram from Figure 102. Connect the test-set input(s) to the relay output(s) that are programmed to operate when the restrained-differential relay operates. 120 Chapter 2: Percent Dif ferential (87) Element Testing 3. Set a single-phase currentat least 200% higher than the Minimum Pickup setting using the calculations in the “1-Phase Pickup Test Procedure” section of this chapter. (1.446A (0.723 × 2.0 = 1.446A ) for Winding-1 or 4.79A (2.395 × 2.0 = 4.79A ) for Winding-2.) 4. Apply the current and make sure the relay differential element operates. 5. Set the harmonic percentage 5% higher than the pickup setting. (25% fora 20% setting) 6. Apply the current and make sure the relay differential element does not operate. 7. Reduce the harmonic percentage to 5%below the pickup setting (15% for a 20%setting) 8. Apply the test current and ensure the relay operates. 9. Increase the harmonic in 1% increments and apply until the relay does not operate. 10. Return to the last test harmonic when the element operated and increase the harmonic in 0.1% increments and apply until the relay does not operate. This is the Harmonic Restraint pickup result. Record on your test sheet. 11. Repeat steps 3-10 for all phases. DIFFERENTIAL TEST RESULTS PICK UP 0.3 0 PCT2 15 SLOPE 1 20% TIME DELAY TAP1 2.41 PCT4 15 SLOPE 2 60% TAP2 4.61 PCT5 35 HARMONIC RESTRAINT TESTS (Amps) TEST HARMONIC 1 2nd 2 4th 3 5th IAW1 (%) IBW1 (%) ICW1 (%) 14.8 15.2 34.8 1 5 .2 15.3 35.6 15.1 15.6 35.9 EXPECTED (%) 1.7 % ERROR 15.0 -1.3 1.3 0.7 15.0 1.3 2.0 4.0 35.0 2.6 -0.6 121 The Relay Testing Handbook C) Harmonic RestraintTest Procedurewith Current Testing without a harmonic setting on your test-set requires two current channels connected in parallel with one current channel set at the fundamental frequency (60 Hz in our example) and the second current at the harmonic frequency. Harmonics are described in multiples of the fundamental frequency so a nd2 harmonic would be 120 Hz in our example or 100 Hz in a system with a 50Hz nominal frequency. As described in the previous section, different relays have different operating characteristics when applying harmonic restraint and we’ll use the pulse method with the following procedure. 1. Apply the connection diagram from Figure 103. Connect the test-set input(s) to the relay output(s) that are programmed to operate when the restrained-differential relay operates. 2. Set the current Channel 1 at the fundamental frequency (60Hz) with a magnitude at least 200% higher than the Minimum Pickup setting using the calculations in the “1-Phase Pickup Test Procedure” section of this chapter. (1.446A(0.723 × 2.0 = 1.446A ) for Winding-1 or 4.79A (2.395 × 2.0 = 4.79A ) for Winding-2) Apply the current and make sure the relay differential element operates. 3. Set the current 2 Channel frequency to the full harmonic frequency. (2nd = 120 Hz, 4th = 240Hz, 5th = 300Hz) We’ll call this “harmonic current” from now on. 4. Multiply the harmonic pickup setting (PCT2=15%) by the applied current from Step 2 (1.446 × 0.15 = 0.217A ) . This is your expected current. 5. Set your test-set’s harmonic current output 10% higher than the expected harmonic current (0.217 × 1.10 = 0.239A ) . Apply the fundamental and harmonic currents simultaneously and the relay should not operate. 6. Reduce the harmonic percentage to 5% below the expected current0.217 x 0.95 = ( 0.206A) and apply the fundamental and harmonic currents simultaneously. The relay should operate. 7. Increase the harmonic current in 1% increments and apply until the relay does not operate. 8. Return to the last test harmonic when the element operated, and increase the harmonic in 0.1% increments and apply until the relay does not operate. This is the Harmonic Restraint pickup result. Record on your test sheet. 9. Repeat steps 2-8 for all phases. 122 Chapter 2: Percent Dif ferential (87) Element Testing DIFFERENTIAL TEST RESULTS PICK UP 0.3 0 PCT2 15 SLOPE 1 20% TIME DELAY TAP1 2.41 PCT4 15 SLOPE 2 60% TAP2 4.61 PCT5 35 HARMONIC RESTRAINT TESTS (Amps) HARM FUND IAW1 (A) PCT2 1.446 A PCT4 1.446 A PCT5 1.446 A IBW1 (A) 0.214 0.220 0.503 ICW1 (A) 0.220 0.221 0.515 EXPECTED(A) 0.218 0.226 0.519 %ERROR 0.217 -1.4 1.3 0.217 1.3 2 .0 0.506 -0 . 6 1 .7 0.6 4.0 2.6 D) Evaluate Results Use the harmonic specifications below to determine if the test results are acceptable. All of the example test results are less than 5% so we do not need to proceed further We could calculate the exact allowable percent error with the following calculation which is a huge number because of the very low expected current: Maximum Accuracy Tolerance × 100 = Allowable Percent Error EXPECTED (5.0% ×EXP ECTED ) + 0.1A × EXPECTED ( 0.05 ×0. 217 ) + 0.1A 0.217A (0.011) + 0.1A × 0.217A 100 = Allowable Percent Error × 100 = Allowable Percent Error 100 = Allowable Percent Error 0.111 × 100 = Allowable Percent Error 0.217A 51% Allowable Percent Error 123 The Relay Testing Handbook 9. Tips and Tricks to Overcome Common Obstacles The following tips or tricks may help you overcome the most common obstacles: • • • • • • • • 124 Before you start, apply current at a lower value and review the relay’s measured values to make sure your test-set is actually producing an output and your connections are correct. Are the 2 winding currents 180º apart? If the pickup tests are off by a 3 , 1.5, or 0.577 multiple; the relay probably is applying correction factors, and you should review the manufacturer’s literature. Are you applying the currents into the same phase relationships? Did you calculate the correct Tap? Don’t forget to use the complete operate and restrained calculations. Always use a Wye-connected winding’s phase A as the reference when setting angles. If a Delta-winding is set as the reference, the phase shift will look backwards. Slope-2 tests near the break point can yield seemingly erratic results. Try a test point further from the break point. Chapter 3: Unrestrained Dif ferential Testing Chapter 3 Unrestrained-DifferentialTesting Electrical engineers are always concerned about close-onto-fault conditions, especially with transformer protection. What would happen if a transformer circuit breaker closed onto a fault in the first-energized winding? It is conceivable that the inrush condition could mask the fault for several cycles and cause additional damage or system disturbances. Additional protection can be applied which is set higher than the expected inrush current to detect faults on the first-energized winding of the transformer. The unrestrained-differential element operation is very much like the early differential relays described in the “Application” section of this chapter as shown in Figure 104. There are no restraint coils to prevent mis-operations at high current levels and, in fact, the element is typically set at 8-10x Tap. 1000 A 100:5 CT G 100:5 CT FAULT Iop = 10.0 A I1=45.0A I2=55.0A Figure 104: Simple Differential Protection with Worst Case CT Error and External Fault With pickup settings in the 8-10x Tap range, unrestrained-differential protection becomes nearly identical the Instantaneous The RelaytoTesting Handbook. Overcurrent (50-Element) test procedures in previous packages of 125 The Relay Testing Handbook 1. Settings A) Enable Setting Many relays allow the user toenable or disable settings. Make sure that the element is ON or the relay may prevent you from entering settings. Ifthe element is not used, the setting should be disabled or OFF to prevent confusion. Some relays will also have “Latched” or ‘Unlatched” options. A Latched option indicates that the output contacts will remain closed afterrelay a tripoutput until acontacts reset iswill performed andthe actstrip as conditions a lockout relay. indicates that the open when are noUnlatched longer present. B) Minimum Pickup The Minimum Pickup setting is usually set in multiples of Tap and is the minimum amount of current required for the relay to operate. C) Tap The Tap setting defines the normal operate current based on the rated load of the protected equipment, the primary voltage, and the CT ratio. This setting is used as the per-unit operate current of the protected device and most differential settings are based on the Tap setting. Verify the correct Tap setting using the following formula: TAP = CTSEC × Power P-P Volts × 3 ×CT D) Time Delay The Time Delay setting sets a time delay between an 87-Element pickup and trip. This setting is typically set at the minimum possible setting but can be set as high as cycles 3 for maximum reliability on some relays. E) Block The Block setting defines a condition that will prevent the differential protection from operating such as a status input from another device. This setting is rarely used. If enabled, make sure the condition is not true when testing. Always verify correct blocking operation by operating the end-device instead of a simulation to ensure the block has been correctly applied. 126 Chapter 3: Unrestrained Dif ferential Testing 2. Test-Set Connections The most basic test-set connection uses only one phase of the test-set with a test lead change between every pickup test. After the Winding-1 A-phase pickup test is performed, move the test leads from Winding-1 A-Phase amps to B-Phase amps and perform the test again. Repeat until all enabled phases are tested. RELAY INPUT RELAY AØ PU WINDING 1 A Phase Input=Pickup A Phase Amps RELAY TEST SET Mag ni tu d e + + + + + + B Phase Amps C Phase Amps C1 Amps AØTestAmps P h a s eA n g le Frequency 0° Test Hz C2 Amps C3 Amps WINDING 2 A Phase Amps B Phase Amps C Phase Amps Element Output + + + + + Timer Input Alternate Timer Connection + DC Supply Element Output + Timer Input Figure 105: Simple 87U-Element Test-Set Connections 127 The Relay Testing Handbook This element will require a lot of current so the connection in Figure 106 will probably be required if you treat the element as a 50-Element. RELAY INPUT C1 Amps C2 Amps C3 Amps RELAY RELAY TEST SET M a g n i tu d e WINDING 1 + A Phase Amps B Phase Amps P h a se A n g l e Frequency + + + + + C Phase Amps C1 Amps Test Amps / 3 0° Test Hz C2 Amps Test Amps / 3 0° Test Hz C3 Amps Test Amps / 3 0° Test Hz WINDING 2 + A Phase Amps + B Phase Amps + C Phase Amps Element Output + + Timer Input Alternate Timer Connection + DC Supply - Element Output + Timer Input Figure 106: Parallel 87U-Element Test-Set Connections If we realize that two different relay inputs are used to create the operate current, we can minimize the impact on any relay input by splitting the test current into the analog inputs that operate the unrestrained-differential element as shown in Figure 107. This connection also checks two windings simultaneously and reduces test times. W1 RELAY INPUT W2 RELAY INPUT W2 W1 RELAY RELAY TEST SET M a g n i tu d e WINDING 1 + B Phase Amps P h a se A n g l e Frequency + A Phase Amps C1 Amps + + + + C Phase Amps C2 Amps W1TestAmps 0° 0.00A C3 Amps W2TestAmps Timer Input Element Output Test Hz 0° Test Hz 0° TestHz WINDING 2 + A Phase Amps + B Phase Amps + C Phase Amps Alternate Timer Connection + DC Supply - + Element Output + + Timer Input Figure 107: Parallel 87U-Element Test-Set Connections with Equal W_CTC Settings 128 Chapter 3: Unrestrained Dif ferential Testing The connection diagram in Figure 107 only works correctly if both W_CTC settings are identical. If the W_CTC settings are not identical, we need to apply the chart in Figure 108 to apply a connection diagram such as shownin the following connection drawings: GE T-6 0, T-3 0 S R-7 45 W1=0, W2=0 W1=0, W2=30° W1=0, W2=330° Y/y0° Y/d30° Y/d330° D/d0° D/d0° W1=0, W2=30° W1=0, W2=330° D/y30° D/y330° B e c kwit h S E L -5 8 7 Yyyy YDACyy YDAByy YY YDAC DACY S E L - 38 7 W1 W2 12 12 12 12 1 11 12 DACDACyy DACDAC 0 0 0 DABYyy DACyy DABY DACY 0 0 BPh a s e W1 W2 C - Pha s e W1 W2 A- B A- B B- C B- C C- A C- A A- C A- N B- A B- N C- B C- N A- B A- N B- C B- N C- A C- N 0 A- B A- B B- C B- C C- A C- A A- N A- N B- N B- N C- N C- N 12 1 11 1 1 1 11 11 11 AP ha s e W1 W2 A- B A- C A- B 0 12 1 0 12 11 A- B B- C B- C C- A C- A A- N B- A B- N C- B C- N A- N B- C B- N C- A C- N A- N A- C B- N B- A C- N C- B A- N A- C B- N B- A C- N C- B A- N A- N B- N B- N C- N C- N A- N A- B B- N B- C C- N C- A A- N A- B B- N B- C C- N C- A A- N A- N B- N B- N C- N C- N Figure 108: Transformer Relay Connections for Single-Phase Differential Testing The winding settings for our example transformer are W1CTC=12 and W2CTC=1. Using the table in Figure 108, the following test-set connections will be required for A-Phase. Use the chart to determine connections for B and C-Phase testing. S E L -3 8R 7E L A Y R E L AT YE SS TE T WINDING 1 Z01 IAW1 Z02 + + Z03 + + + + IBW1 ICW1 Z04 Z05 Z06 WINDING 2 Z07 IAW2 Z08 + Z09 + IBW2 ICW2 M a g n i tu d e P h a s e A n g le Frequency C1 Amps W1AØT estAmps 0° Test Hz C2 Amps W2AØ Test Amps 0° Test Hz C3 Amps 0.00A 0° Test Hz Z10 Z11 + Z12 Alternate Timer Connection +DC Supply Element Output + + Timer Input Element Output + Timer Input Figure 109: 1-Phase Differential Test-Set AØ Yd1 Connections 129 The Relay Testing Handbook 3. Simple Pickup Test Procedure The simple unrestrained-differential pickup test procedure is identical to an Instantaneous Overcurrent test procedure; • • • • Apply a current into one-phase higher than the pickup setting and make sure pickup indication operates. Apply a current lower than pickup setting and make sure pickup indication does NOT operate. Raise current until pickup indication operates. Repeat for all phases. A single-phase test procedure is slightly more complicated because correction factors may apply. Digital transformer relays use algorithms to compensate for the different transformer phase shifts as described earlier and apply compensation factors to compare windings with different configurations. The compensation factors for the example SEL-387 can be found in the Testing and Troubleshooting section of the instruction manual as shown in the following table: WNCTC SET TING A 0 Odd:1,3,5,7,9,11 Even:2,4,6,8,10,12 1 √3 1.5 However, the table does not seem to be correct when the WnCTC equals 12. We have found through experimentation that the correction factor is actually 1. The following settings will be used for our SEL-387 example. • • • Tap1 = 2.41 Tap2 = 4.61 U87P = 10 (xTap) Use the following steps to determine pickup: 1. Determine how you will monitor pickup and set the relay accordingly (if required). (Pickup The indication by LED, output contact, front panel display, etc…See previous packages of Relay Testing Handbook for details.) 130 Chapter 3: Unrestrained Dif ferential Testing 2. Determine the expected pickup. W I N DI N G 1 WIN D IN G 2 Minimum Pickup = U87P × TAP1 × A Minimum Pickup = U87P × TAP2 ×A Minimum Pickup = 10 × 2.41 × = (12 1)1 Minimum Pickup = 10 × 4.61 × = (1 Minimum Pickup = 24.1A 3) 3 Minimum Pickup = 79.845A 3. Set the fault current 5% higher than the pickup setting. For example, set the fault current at 25.305A (24.1 × 1.05 = 25.305A ) for Winding-1 or 83.837A (79.845 × 1.05 = 83.837A ) for Winding-2. Make sure pickup indication operates. 4. Reduce the fault current 5% below the expected current and apply the fault current momentarily. The relay should not operate. 5. Increase the fault current in 1% increments and apply until the relay does operate. 6. Return to the last test current when the element did not operate and increase the fault current in 0.1% increments and apply until the relay operates. This is the pickup result. Record on your test sheet. 7. Repeat steps 2-6 for all phases. 8. Compare the pickup test result to the manufacturer’s specifications and calculate the percent error as shown in the following example. The 87U-Element pickup Winding-1 pickup setting is 24.1A and the measured pickup was 24.21A. Looking at the “Differential” specification in Figure 110, we see that the acceptable metering error is ±5% ±0.10A. Differential Element Unrestrained Pickup Range: 1–20 in per unit of tap Restrained Pickup Range: 0.1–1.0 in per unit of tap Pickup Accuracy (A secondary) 5 A Model: 1 A Model: ±5% ±0.10 A ±5% ±0.02 A Unrestrained Element Pickup Time (Min/Typ/Max): 0.8/1.0/1.9 cycles Restrained Element (with harmonic Blocking) Pickup Time (Min/Typ/Max): 1.5/1.6/2.2 cycles Restrained Element (with harmonic Restraint) Pickup Time (Min/Typ/Max): 2.62/2.72/2.86 cycles Figure 110: SEL-387E Specifications 131 The Relay Testing Handbook We can calculate the manufacturer’s allowable percent error for Winding-1. 100 × (5% ×Set ting ) + 0.1A 100 × Setting (5% ×24 .1 ) + 0.1A 24.1 100 × 1.305 = Allowable Percent Error = Allowable Percent Error = Allowable Percent Error 24.1 5.41% Allowable Percent Error The measured percent error can be calculated using the percent error formula below: Actual Value - Expected Value × 100 = Percent Error Expected Value 24.21A - 24.1A × 100 = Percent Error 24.1A 0.46% Error The Winding-1 test is within the manufacturer’s tolerance of 5.41% and passed the test. 9. Repeat the pickup test for all phase currents that are part of the differential scheme. DIFFERENTIAL TEST RESULTS 87U PICK UP TAP1 10 2.41 TIME DELAY TAP2 0 4.61 UNRESTRAINED PICKUP TESTS (Amps) IAW_(A) W1 W2 132 24.210 79.850 IBW_(A) 24.150 78.860 ICW_(A) 24.130 79.840 EXPECTED(A) %ERROR 24.100 0.5 0.2 0.1 79.845 0.0 -1.2 0.0 Chapter 3: Unrestrained Dif ferential Testing 4. Alternate Pickup Test Procedure Unrestrained-differential elements are, by definition, high-current applications. Adding a 1.73 correction factor for single-phase testing can often put the expected pickup above the maximum output of your test-set. We can use the testing philosophy from the “1-Phase Restrained-Differential Slope Testing” section of the previous chapter to apply equal currents in two windings simultaneously while in-phase to minimize the required current to test the Unrestrained-Differential element. The following settings will be used for our SEL-387 example. • • • • • W1CTC = 12 W1CTC = 1 Tap1 = 2.41 Tap2 = 4.61 U87P = 10 (xTap) 1. Connect the test-set as per Figures 108 and 109 and the descriptions in the “1-Phase Restrained-Differential Slope Testing” section of the previous chapter. 2. Determine how you will monitor pickup and set the er lay accordingly, if required. (Pickup The indication by LED, output contact, front panel display, etc…See previous packages of Relay Testing Handbook for details.) 133 The Relay Testing Handbook 3. Use the following formula to calculate equal currents for any multiple of Tap using the following table for correction factors. WNCTC SET TING A 0 1 Odd:1,3,5,7,9,11 √3 Even:2,4,6,8,10,12 1.5 However, the table does not seem to be correct when the WnCTC equals 12. We have found through experimentation that the correction factor is, in fact, 1. Test Amps Test Amps + = Test@Tap TAP1 ×A1 TAP2 ×A2 TAP1 ×A1  Test Amps Test Amps  + = × ×  Test@Tap TAP1 A1  TAP1 TAP2 ×A2  ×A1  TAP1 × A1 × Test Amps   =  TestAmps + ×× Test@Tap TAP1 A1 TAP2   TAP1 × Test Amps   TAP2 × A2 ×  Test Amps + × ×TAP1 × × A1 TAP2 A2  = Test@Tap TAP2   + × × TAP1 ( TAP2 × ×A2 ( Test) Amps ) × ( TAP2 × A2+TAP1 A1 = Test ×Amps ×× ×Test@Tap TAP1 A1 TAP2 A2 A1 ) Test= Amps × Test@Tap TAP1 A1 TAP2 A2 ×× × Test Amps = Test@Tap × TAP1 × × A1 × TAP2 A2 ( TAP1 ×()A1 + TAP2 ×A2  ) Test Amps = Test@Tap × TAP1 × × A1 × TAP2 A2 ( TAP1 ×()A1 + TAP2 ×A2  ) Test Amps = 10 × 2.41 ×× 1 ×4.61 1.7 32 ()× 1 + 4.61 ) ×1.732  ( 2.41 Test Amps = 192.43 10.39 Test Amps = 18.52 4. Momentarily apply 10% more current (Pickup × 1.1 = 18.52A × = 1.1 20.732A ) from all applied test-set current channels and ensure the relay operates. 134 Chapter 3: Unrestrained Dif ferential Testing 5. Lower the currents to 95% of the pickup setting Pickup ( 18.52A × 0.95 = × = 0.95 17.594A ) and momentarily apply. The pickup indication should remain OFF. 6. Raise the currents in 1% increments and momentarily apply until the pickup indication turns ON. 7. Subtract 1% and increase in 0.1% steps until the pickup operates. This is the 87U pickup. Use the following formula to determine the pickup in per-unit: Per Unit Pickup = Test Amps Test Amps + TAP1 ×A1 TAP2 ×A2 8. Change all connections for B phase and repeat steps 4-7. 9. Change all connections for C phase and repeat steps 4-7. 10. Evaluate the results using “Pickup Accuracy (A Secondary): 5 A Model” from the SEL-387 specification in Figure 111. Figure 111: SEL-387 Differential Element Specifications DIFFERENTIAL TEST RESULTS 87U PICK UP TAP1 10 2.41 TIME DELAY TAP2 0 4.61 UNRESTRAINED PICKUP TESTS (Amps) 87U1 18.550 IAW1,IAW2&ICW2 87U2 18.530 IBW1,IBW2&IAW2 87U3 18.540 EXPECTED (A) 18.520 % ERROR 0.2 0. 1 0.1 ICW1,ICW2&IBW2 135 The Relay Testing Handbook 5. Timing Test Procedure 1. Connect the relay output contact to the test-set input. 2. Apply the connections from the Simple or Alternate Pickup Test Procedure from the previous sections in this chapter. 3. Set the test current 110% of the expected current using the same test procedure in Step 2. 4. Configure a test that applies the test current and starts the fault timer simultaneously. The timer and current output should stop when the relay output operates. 5. Apply the test and record the results. 6. Change the connections for the next phase and repeat the test. 7. Change the connections for the next phase and repeat. 8. Evaluate the results using “Unrestrained Element Pickup Time” from the SEL-387 Time” specifications in Figure 112. specification in Figure 111 and the Output ContactPickup “ Output Contacts: Standard: Make: 30 A; Carry: 6 A continuous carry at 70°C, 4 Acontinuous at 85°C: 1 s Rating: 50 A: MOV protected: 270 Vac, 360 Vdc, 40 J; Pickup time: Less than 5 ms; Dropout time: Less than 5 ms typical. Figure 112: Preferred SEL-387 Output Contact Specifications Maximum Operating Time = Unrestrained Element Pickup Time(Max) + Output Contact Pickup Time Maximum Operating Time = 1.9cycles + < 5ms Maximum Operating Time = 1.9 cycles + 4.99 ms 60 Maximum Operating Time = 31.67ms + 4.99 ms Maximum Operating Time = 0.0367ms or 2.20cycles 136 Chapter 3: Unrestrained Dif ferential Testing 6. Tips and Tricks to Overcome Common Obstacles The following tips or tricks may help you overcome the most common obstacles. • • • • • Before you start, apply current at a lower value and review the relay’s measured values to make sure your test-set is actually producing an output and your connections are correct. Are the 2 winding currents 0º apart? If the pickup tests are off by a 3 , 1.5, or 0.577 multiple; the relay probably is applying correction factors and you should review the manufacturer’s literature. Are you applying the currents into the same phase relationships? Did you calculate the correct Tap? 137 The Relay Testing Handbook 138 Bibliography Bibliography Tang, Kenneth, Dynamic State & Other Advanced Testing Methods for Protection Relays Address Changing Industry Needs Manta Test Systems Inc, www.mantatest.com Tang, Kenneth, A True Understanding of R-X Diagrams and Impedance Relay Characteristics Manta Test Systems Inc, www.mantatest.com Blackburn, J. 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Elmore, Walter A., (Editor) (1994)Protective Relaying Theory and Applications (Red Book) ABB GEC Alstom (Reprint March 1995)Protective Relays Application Guide (Blue Book), Third Edition GEC Alstom T&D Schweitzer Engineering Laboratories (20011003) SEL-300G Multifunction Generator Relay Overcurrent Relay Instruction Manual Pullman, WA, www.selinc.com Schweitzer Engineering Laboratories (20010625)SEL-311C Protection and Automation System Instruction Manual Pullman, WA, www.selinc.com Schweitzer Engineering Laboratories (20010808) SEL-351A Distribution Protection System, Directional Overcurrent Relay, Reclosing Relay, Fault Locator, Integration Element Standard Instruction Manual Pullman, WA, www.selinc.com Costello, David and Gregory, Jeff (AG2000-01)Application Guide Volume IV Determining the Correct TRCON Setting in the SEL-587 Relay When Applied to Delta-Wye Power Transformers Pullman, WA, Schweitzer EngineeringLaboratories, www.selinc.com Schweitzer Engineering Laboratories (20010606) SEL-587-0, -1 Current Differential Relay Overcurrent Relay Instruction Manual Pullman, WA, www.selinc.com 139 The Relay Testing Handbook Schweitzer Engineering Laboratories (20010910)SEL-387-0, -5, -6 Current Differential Relay Overcurrent Relay Data Recorder Instruction Manual Pullman, WA, www.selinc.com GE Power Management (1601-0071-E7)489 Generator Management Relay Instruction Manual Markham, Ontario, Canada, www.geindustrial.com GE Power Management (1601-0044-AM (GEK-106293B))750/760 Feeder Management Relay Instruction Manual Markham, Ontario, Canada, www.geindustrial.com GE Power Management (1601-0070-B1 (GEK-106292))745 Transformer Management Relay Instruction Manual Markham, Ontario, Canada, www.geindustrial.com GE Power Management (1601-0110-P2 (GEK-113321A))G60 Generator Management Relay: UR Series Instruction Manual Markham, Ontario, Canada, www.geindustrial.com GE Power Management (1601-0089-P2 (GEK-113317A))D60 Line Distance Relay: Instruction Manual Markham, Ontario, Canada, www.geindustrial.com GE Power Management (1601-0090-N3 (GEK-113280B))T60 Transformer Management Relay: UR Series Instruction Manual Markham, Ontario, Canada, www.geindustrial.com Beckwith Electric Co. Inc.M-3420 Generator Protection Instruction Book Largo, FL, www.beckwithelectric.com Beckwith Electric Co. Inc.M-3425 Generator Protection Instruction Book Largo, FL, www.beckwithelectric.com Beckwith Electric Co. Inc. M-3310 Transformer Protection Relay Instruction Book 800-3310-IB08MC1 02/03 Largo, FL, www.beckwithelectric.com Young, Mike and Closson, James, Commissioning Numerical Relays Basler Electric Company, www.baslerelectric.com Basler Electric Company (ECNE 10/92)Generator Protection Using Multifunction Digital Relays www.baslerelectric.com I.E.E.E., (C37.102-1995)IEEE Guide for AC Generator Protection Avo International (Bulletin-1 FMS 7/99) Type FMS Semiflush-Mounted Test Switches 140 Bibliography Cutler-Hammer Products (Application Data 36-693)Type CLS High Voltage Power Fuses Pittsburg, Pennsylvania GE Power Management,PK-2 Test Blocks and Plugs T. Giuliante, ATG Consulting, M. Makki, Softstuf, and Jeff Taffuri, Con Edison; New Techniques For Dynamic Relay Testing 141