000 12447nam a2200565 i 4500
001 7159541
003 IEEE
005 20220712205918.0
006 m o d
007 cr |n|||||||||
008 151222s2015 nju ob 001 eng d
010 _z 2014021807 (print)
020 _a9781118653838
_qelectronic
020 _z9781118653821
_qhardback
024 7 _a10.1002/9781118653838
_2doi
035 _a(CaBNVSL)mat07159541
035 _a(IDAMS)0b0000648492070d
040 _aCaBNVSL
_beng
_erda
_cCaBNVSL
_dCaBNVSL
050 4 _aTK2861
_b.E4233 2014eb
082 0 0 _a621.31/4
_223
100 1 _aLin, Xiangning,
_eauthor.
_928652
245 1 0 _aElectromagnetic transient analysis and novel protective relaying techniques for power transformer /
_cXiangning Lin, Jing Ma, Qing Tian, Hanli Weng.
264 1 _aSingapore :
_bJohn Wiley & Sons, Inc.,
_c2014.
264 2 _a[Piscataqay, New Jersey] :
_bIEEE Xplore,
_c[2015]
300 _a1 PDF (320 pages).
336 _atext
_2rdacontent
337 _aelectronic
_2isbdmedia
338 _aonline resource
_2rdacarrier
504 _aIncludes bibliographical references and index.
505 0 _aAbout the Authors ix -- Preface xi -- 1 Principles of Transformer Differential Protection and Existing Problem Analysis 1 -- 1.1 Introduction 1 -- 1.2 Fundamentals of Transformer Differential Protection 2 -- 1.2.1 Transformer Faults 2 -- 1.2.2 Differential Protection of Transformers 3 -- 1.2.3 The Unbalanced Current and Measures to Eliminate Its Effect 5 -- 1.3 Some Problems with Power Transformer Main Protection 7 -- 1.3.1 Other Types of Power Transformer Differential Protections 7 -- 1.3.2 Research on Novel Protection Principles 9 -- 1.4 Analysis of Electromagnetic Transients and Adaptability of Second Harmonic Restraint Based Differential Protection of a UHV Power Transformer 17 -- 1.4.1 Modelling of the UHV Power Transformer 18 -- 1.4.2 Simulation and Analysis 20 -- 1.5 Study on Comparisons among Some Waveform Symmetry Principle Based Transformer Differential Protection 27 -- 1.5.1 The Comparison and Analysis of Several Kinds of Symmetrical Waveform Theories 27 -- 1.5.2 The Theory of Waveform Symmetry of Derivatives of Current and Its Analysis 28 -- 1.5.3 Principle and Analysis of the Waveform Correlation Method 32 -- 1.5.4 Analysis of Reliability and Sensitivity of Several Criteria 33 -- 1.6 Summary 36 -- References 36 -- 2 Malfunction Mechanism Analysis due to Nonlinearity of Transformer Core 39 -- 2.1 Introduction 39 -- 2.2 The Ultra-Saturation Phenomenon of Loaded Transformer Energizing and its Impacts on Differential Protection 43 -- 2.2.1 Loaded Transformer Energizing Model Based on Second Order Equivalent Circuit 43 -- 2.2.2 Preliminary Simulation Studies 48 -- 2.3 Studies on the Unusual Mal-Operation of Transformer Differential Protection during the Nonlinear Load Switch-In 57 -- 2.3.1 Simulation Model of the Nonlinear Load Switch-In 57 -- 2.3.2 Simulation Results and Analysis of Mal-Operation Mechanism of Differential Protection 62 -- 2.4 Analysis of a Sort of Unusual Mal-operation of Transformer Differential Protection due to Removal of External Fault 70.
505 8 _a2.4.1 Modelling of the External Fault Inception and Removal and Current Transformer 70 -- 2.4.2 Analysis of Low Current Mal-operation of Differential Protection 72 -- 2.5 Analysis and Countermeasure of Abnormal Operation Behaviours of the Differential Protection of the Converter Transformer 80 -- 2.5.1 Recurrence and Analysis of the Reported Abnormal Operation of the Differential Protection of the Converter Transformer 80 -- 2.5.2 Time-Difference Criterion to Discriminate between Faults and Magnetizing Inrushes of the Converter Transformer 86 -- 2.6 Summary 95 -- References 95 -- 3 Novel Analysis Tools on Operating Characteristics of Transformer Differential Protection 97 -- 3.1 Introduction 97 -- 3.2 Studies on the Operation Behaviour of Differential Protection during a Loaded Transformer Energizing 99 -- 3.2.1 Simulation Models of Loaded Transformer Switch-On and CT 99 -- 3.2.2 Analysis of the Mal-operation Mechanism of Differential Protection 102 -- 3.3 Comparative Investigation on Current Differential Criteria between One Using Phase Current and One Using Phase-Phase Current Difference for the Transformer using Y-Delta Connection 109 -- 3.3.1 Analyses of Applying the Phase Current Differential to the Power Transformer with Y/(SE(B Connection and its Existing Bases 109 -- 3.3.2 Rationality Analyses of Applying the Phase Current Differential Criterion to the Power Transformer with Y/(SE(B Connection 113 -- 3.4 Comparative Analysis on Current Percentage Differential Protections Using a Novel Reliability Evaluation Criterion 117 -- 3.4.1 Introduction to CPD and NPD 117 -- 3.4.2 Performance Comparison between CPD and NPD in the Case of CT Saturation 118 -- 3.4.3 Performance Comparison between CPD and NPD in the Case of Internal Fault 121 -- 3.5 Comparative Studies on Percentage Differential Criteria Using Phase Current and Superimposed Phase Current 123 -- 3.5.1 The Dynamic Locus of p - 1p +1 in the Case of CT Saturation 123 -- 3.5.2 Sensitivity Comparison between the Phase Current Based and the Superimposed Current Based Differential Criteria 126.
505 8 _a3.5.3 Security Comparison between the Phase Current Based and the Superimposed Current Based Differential Criteria 128 -- 3.5.4 Simulation Analyses 130 -- 3.6 A Novel Analysis Methodology of Differential Protection Operation Behaviour 132 -- 3.6.1 The Relationship between Transforming Rate and the Angular Change Rate under CT Saturation 132 -- 3.6.2 Principles of Novel Percentage Restraint Criteria 133 -- 3.6.3 Analysis of Novel Percentage Differential Criteria 142 -- 3.7 Summary 151 -- References 151 -- 4 Novel Magnetizing Inrush Identification Schemes 153 -- 4.1 Introduction 153 -- 4.2 Studies for Identification of the Inrush Based on Improved Correlation Algorithm 155 -- 4.2.1 Basic Principle of Waveform Correlation Scheme 155 -- 4.2.2 Design and Test of the Improved Waveform Correlation Principle 159 -- 4.3 A Novel Method for Discrimination of Internal Faults and Inrush Currents by Using Waveform Singularity Factor 163 -- 4.3.1 Waveform Singularity Factor Based Algorithm 163 -- 4.3.2 Testing Results and Analysis 164 -- 4.4 A New Principle of Discrimination between Inrush Current and Internal Fault Current of Transformer Based on Self-Correlation Function 169 -- 4.4.1 Basic Principle of Correlation Function Applied to Random Single Analysis 169 -- 4.4.2 Theory and Analysis of Waveform Similarity Based on Self-Correlation Function 170 -- 4.4.3 EPDL Testing Results and Analysis 173 -- 4.5 Identifying Inrush Current Using Sinusoidal Proximity Factor 174 -- 4.5.1 Sinusoidal Proximity Factor Based Algorithm 174 -- 4.5.2 Testing Results and Analysis 176 -- 4.6 A Wavelet Transform Based Scheme for Power Transformer Inrush Identification 181 -- 4.6.1 Principle of Wavelet Transform 181 -- 4.6.2 Inrush Identification with WPT 185 -- 4.6.3 Results and Analysis 185 -- 4.7 A Novel Adaptive Scheme of Discrimination between Internal Faults and Inrush Currents of Transformer Using Mathematical Morphology 190 -- 4.7.1 Mathematical Morphology 190 -- 4.7.2 Principle and Scheme Design 193.
505 8 _a4.7.3 Testing Results and Analysis 194 -- 4.8 Identifying Transformer Inrush Current Based on Normalized Grille Curve 202 -- 4.8.1 Normalized Grille Curve 202 -- 4.8.2 Experimental System 205 -- 4.8.3 Testing Results and Analysis 207 -- 4.9 A Novel Algorithm for Discrimination between Inrush Currents and Internal Faults Based on Equivalent Instantaneous Leakage Inductance 211 -- 4.9.1 Basic Principle 211 -- 4.9.2 EILI-Based Criterion 217 -- 4.9.3 Experimental Results and Analysis 218 -- 4.10 A Two-Terminal Network-Based Method for Discrimination between Internal Faults and Inrush Currents 222 -- 4.10.1 Basic Principle 222 -- 4.10.2 Experimental System 230 -- 4.10.3 Testing Results and Analysis 230 -- 4.11 Summary 234 -- References 234 -- 5 Comprehensive Countermeasures for Improving the Performance of Transformer Differential Protection 237 -- 5.1 Introduction 237 -- 5.2 A Method to Eliminate the Magnetizing Inrush Current of Energized Transformers 242 -- 5.2.1 Principles and Modelling of the Inrush Suppressor and Parameter Design 242 -- 5.2.2 Simulation Validation and Results Analysis 249 -- 5.3 Identification of the Cross-Country Fault of a Power Transformer for Fast Unblocking of Differential Protection 255 -- 5.3.1 Criterion for Identifying Cross-Country Faults Using the Variation of the Saturated Secondary Current with Respect to the Differential Current 255 -- 5.3.2 Simulation Analyses and Test Verification 257 -- 5.4 Adaptive Scheme in the Transformer Main Protection 268 -- 5.4.1 The Fundamental of the Time Difference Based Method to Discriminate between the Fault Current and the Inrush of the Transformer 268 -- 5.4.2 Preset Filter 269 -- 5.4.3 Comprehensive Protection Scheme 271 -- 5.4.4 Simulation Tests and Analysis 274 -- 5.5 A Series Multiresolution Morphological Gradient Based Criterion to Identify CT Saturation 294 -- 5.5.1 Time Difference Extraction Criterion Using Mathematical Morphology 294 -- 5.5.2 Simulation Study and Results Analysis 297 -- 5.5.3 Performance Verification with On-site Data 302.
505 8 _a5.6 A New Adaptive Method to Identify CT Saturation Using a Grille Fractal 304 -- 5.6.1 Analysis of the Behaviour of CT Transient Saturation 304 -- 5.6.2 The Basic Principle and Algorithm of Grille Fractal 308 -- 5.6.3 Self-Adaptive Generalized Morphological Filter 312 -- 5.6.4 The Design of Protection Program and the Verification of Results 313 -- 5.7 Summary 317 -- References 317 -- Index 319.
506 1 _aRestricted to subscribers or individual electronic text purchasers.
520 _a"An advanced level examination of the latest developments in power transformer protection This book addresses the technical challenges of transformer malfunction analysis as well as protection. One of the current research directions is the malfunction mechanism analysis due to nonlinearity of transformer core and comprehensive countermeasures on improving the performance of transformer differential protection. Here, the authors summarize their research outcomes and present a set of recent research advances in the electromagnetic transient analysis, the application on power transformer protections, and present a more systematic investigation and review in this field. This research area is still progressing, especially with the fast development of Smart Grid. This book is an important addition to the literature and will enhance significant advancement in research. It is a good reference book for researchers in power transformer protection research and a good text book for graduate and undergraduate students in electrical engineering.Chapter headings include: Transformer differential protection principle and existing problem analysis; Malfunction mechanism analysis due to nonlinearity of transformer core; Novel analysis tools on operating characteristics of Transformer differential protection; Novel magnetizing inrush identification schemes; Comprehensive countermeasures on improving the performance of transformer differential protection An advanced level examination of the latest developments in power transformer protection Presents a new and systematic view of power transformer protection, enabling readers to design new models and consider fresher design approaches Offers a set of approaches to optimize the power system from a microeconomic point of view "--
_cProvided by publisher.
520 _a"This book addresses the technical challenges of transformer malfunction analysis as well as protection"--
_cProvided by publisher.
530 _aAlso available in print.
538 _aMode of access: World Wide Web
588 _aDescription based on PDF viewed 12/22/2015.
650 0 _aElectric relays.
_928653
650 0 _aElectric transformers
_xProtection.
_928654
650 0 _aTransients (Electricity)
_927871
655 0 _aElectronic books.
_93294
710 2 _aIEEE Xplore (Online Service),
_edistributor.
_928655
710 2 _aWiley,
_epublisher.
_928656
776 0 8 _iPrint version
_z9781118653821
856 4 2 _3Abstract with links to resource
_uhttps://ieeexplore.ieee.org/xpl/bkabstractplus.jsp?bkn=7159541
942 _cEBK
999 _c74411
_d74411