Also by Stanley E. Zocholl In Paperback AC Motor Protection Analyzing and Applying Current Transformers by Stanley E. Zocholl Schweitzer Engineering Laboratories, Inc. Copyright © 2004 Schweitzer Engineering Laboratories, Ine All rights reserved. No par of this publication may be reproduced, stored in 3 retrieval system, or transmitted, in amy form oF by any means, electronic, ‘mechanical, photocopying, recording, or otherwise, without the prior written pemnission of the author and/or publixner. For information, coatiet Schweitzer Engineering Laboratories, Ine.. 2350 NE Hopkins Court, Pullman, WA 99163. Library of Congress Cataloging-in-Publication Dita Zocholl, Stanley E. Analyzing and Applying Current ‘transtormers/ Stanley E. Zocholl p. em. Includes bibliographical references (p. 95) SBN 0.9725026-2-9 1, Electric transformers, 2. Rlectric transformers-Protection, 1. "Title. ‘TK2551 263 2008 Fins Edition: August 2004 Printed and Bound in the United States of America, SEL isa registered trademark of Schweitzer Engineering Laborator Contents Introduction... 2.0.66... cece cece ee ee eee eens 1 Current Transformer Equivalent Circuit .............. 3 Volt-Time Area and Saturated Waveforms ............ 5 The Excitation Curve Computer Simulation Flux Density Limit of the Volt-Time Area ............ 19 The Criterion to Avoid Saturation . Rating Current Transformers for Li Current Transformer Selection Procedure Calculating Current Transformer Burden Limits of the Criterion Statistics of Asymmetry... ACase History . 33 KA Fault With Ideal Current Transformers 29 The Saturation Effect (attres weaneanooees edd 33 kA Fault With Maximum Asymmetry in A-Phase ....... 36 33 kA Fault With Offset in B-Phase and C-Phase ........-. 38 CT Application Rules Ad Ewe Pesos me tbe 40 Transformer Differential Relay Applications ......... 42 Generator Differential Relay Application ..... Bre Bus Differential Relay Applications ................ 54 Percentage Slope Characteri Alpha Plane Differential Characteristic . Determining the Slope for a Given Degree of Saturation ........... Saturation Voltage . sees . 65 Bus and Machine Differential Applications .......... 66 The Effect of Remanent Flux on the Slope Setting ....69 The Impact of High Fault Current on Overcurrent Protection ...............0-e ee eee 72 Limitations of an 80 A Instantaneous Setting ...----- 74 Defining a CT Selection Criterion 77 Maximum Fault Current With an 80 A. Instantaneous et 8 Minimum CT Rating With an 80 A Instantaneous Setting... 82 implementing Instantaneous Overcurrent Elements . . .83 Digital Implementation of Instantaneous Overcurrent Relays . 83 Digital Fitter Performance With CT Saturation The Cosine-Peak Adaptive Filter . ‘A Simple Distortion Index Annex A; Volt-Time Area Computer Simulation ...... 93 References .........-. see e eee eee eee eens 95 Figure 1 Figure 2 Figure 3 Figure 4 Figure 5 Figure 6 Figuie7 Figure 8 Figure 9 Figure 10 Figure 11 Figure 12 Figure 13 Figure 14 Figure 15 Figures Toroid Current Transformer ceeerseeeeeeeee I Current Transformer Equivalent Circuit... 4 econdary Current Waveforms for Various Levels of Excitation (Resistive Burden) 7 Core Flux and Secondary Curent in a CT With a 20-Per-Unit Symmetiical Rating Carrying 10-Per-Unit Current With the Offset Due to 0.010 Second Primary Time Constant (75° Impedance Angle) 8 (C400, 2000:5 Current Transformer Excitation Curve Showing the 300:5 Tap With Knee-Point Tangent and Normal Lines .... vette we 10 Magnetizing Impedance cece DD Equivalent Circuit of a Current Transformer ........... 13 Equivaleat Circuit for the Differential Connection of Current Transformers old B-H Loop and the Slope of the Mean Curve... 16 C400, 2000:5 Cusrent Transformer Computer Simulation 18. C400, 2000:5 Current Transformer With 40 kA Asymimetrival Current... see IB Burden Voltage for Asymmetrical Fault Current 20 Event 1—33 kA ABC Fault at 1.55 Miles on a 230 kV Line (Theoretical —No CT Saturation) ul Secondary Current in a C800, 3000 With 39 KA OTs ‘Three-Phase Fault at 1.55 Miles With 0.066 Primary Time Constant 32 Magnitude and Phase Difference of Sampled Seeondary Current... 9 sore Ceeca cries 3 Figure 16 Figure 17 Figure 18 Figure 19 Figure 20 Figure 21 Figure 22 Figure 23 Figure 24 Figure 25 Figure 26 Figure 27 Figure 28 Figure 29 Figure 30 Figure 31 Figore 32 Figure 33 Figure 34 Figure 35 Event 2—33 KA ARC Fault at 1.55 Miles on a 230 KV Line (CT Saturation Caused by Maximum Offset in A-Phase) : Event 3—33 KA ABC Fault at 1.55 Miles on a 230 kV Line (CT Saturation Caused by Offset in B- and C-Phase) Power Plant Auxiliary Differential Relay Restsnt Curent and ly Is the Differential, Harmonie Content ofthe Different Cuvrent in Figure 19 Plotted in Per Unit of the Fundamental Frequency Secondary Currents 1) and Ip Due to a 58800 A Through Fault Current With Offset. The Differential Current Iy Is Also Plotted, 6000:5 CTs Have Knee-Point Volts of 700 and 500. X/R = 52. Secondary Currents 1y and Ip Due to an Asymmetrical ‘Through Fault of SRR00 A. Adding Burden Resistance Decreases the Differential Current Ty. 6000:5. CTs Knee-Point Voltages of 700 and 500, X/R = 52. Differential Protection ...... Percentage Characteristic... Saturation Due to DC Offset. C200 2000 5 cT. 2.00 Burden, Fault Current 10667 Amp. X/R = 14 - Fundamental Waveforms Extracted by Digital Filter Circle Characteristic 7 Chartcteristie Resembling a Cadioid MATLAB Program Graphic Interface...» VS = 20 Fault Current 106674 - 40 Fault Current 106674. 80 Fault Current 106674. 160 Fault Current 106674 . VS = 80 Fault Current 10667A With Cardio i ss Cras = 160 Fait ante 10667 With Caio ci svat Chances yy 50 Figure 36 Figure 37 Figure 38 Figure 39 Figure 40 Figure 41 Figure 42 Figure 43 Figure 44 Figure 45 Figure 46 Figure 47 Figure 48 Figure 49 Figure 50 Figure 51 Figure $2 Figure 53 Figure sq Figure 55 Figure 56 Slope k Versus CT Saturation Voltage Mulirestraint Bus Differential Vs=40,k=30 00... Operate Signal Versus Restraint VS = 67, k = 44, 40 Percent Remanence - Operate Signal Versus Restraint With 40 Percent Remanence .......ceeeereee = Generator Auxiliary Bus With High Fault Curent. Relay Schematic Showing Measured Signals Signal Extracted With a 200 A Primary CT Current CT and Relay Signals fora 40 kA Fault Using C50, 100:5 CTs... Response to 240 KA Fault Using C200, 200:5 CTs «... Response to 40 kA Fault Using C400, 400:5 CTs Diagram of Bipolar Peak Detector Bipolar Peak Detector Transient Overreach RMS Filter Transient Overreach Conipe to Bipolar Peak Detector Fitter Response, Fault 40 kA, X/R = 20, C100, 200: C1 r. 0.5 W Burden : ce Instantaneous Element Using the Cosine Peale Adaptive Filter . _ Cosine Filter Providing Trip for a Waveform With Low Saturation C400, 200:5, 4500 A Pault With X/R =11.31 Bipolar Peak Filter Providing Trip for a Waveform With High Saturation C50, 200:5, 20 kA Fault With X/R= 11.31 Cosine Filter Providing Trip for a Waveform With No Saturation C100, 200:5, 4kA Symmetrical Fault Current . Mathcad Plot of Current and Flux . 65 67 8 68 i) 1 B % 16 oy ” 9 . 84 84 85 85 87 89 90 a 299 Se ee ee ee pee ee pee Introduction ng of how to The purpose of this book is to develop an understan analyze and apply current transformers (CTs) used as current sources for protective relays. A CT appears to be the simplest of electrical devices. For example, a bushing CT is simply a winding on an insulated core, which becomes a transformer only when placed over a primary conductor as shown in Figure 1 Secondary Winding SPEEA 14 \— x Primary Conductor tT. OT insulated Magnetic Core <r Figure 1 Toroid Current Transformer The opening paragraph of S. D. Moreron's classic paper [| states that the art of calculating current transformer characteristics from ation curve data has been known for some time, Moreton wrote this in 1943 and referred to papers written two years earlier. Today, nearly 60 years later, there is still an abiding interest in this al devices scemingly simplest of elec