Cable system transients : theory, modeling and simulation /
This book provides a systematic and comprehensive introduction to electromagnetic transients in cable systems. --
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| Other Authors: | , |
| Format: | eBook |
| Language: | English |
| Published: |
Singapore :
John Wiley & Sons,
[2015]
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| Subjects: | |
| Online Access: | Connect to the full text of this electronic book |
Table of Contents:
- About the Authors xi
- Preface xiii
- Acknowledgements xv
- 1 Various Cables Used in Practice 1 /Teruo Ohno
- 1.1 Introduction 1
- 1.2 Land Cables 3
- 1.2.1 Introduction 3
- 1.2.2 XLPE Cables 4
- 1.2.3 SCOF Cables 9
- 1.2.4 HPOF Cables 10
- 1.3 Submarine Cables 11
- 1.3.1 Introduction 11
- 1.3.2 HVAC Submarine Cables 11
- 1.3.3 HVDC Submarine Cables 12
- 1.4 Laying Configurations 13
- 1.4.1 Burial Condition 13
- 1.4.2 Sheath Bonding 14
- References 19
- 2 Impedance and Admittance Formulas 21 /Akihiro Ametani
- 2.1 Single-core Coaxial Cable (SC Cable) 22
- 2.1.1 Impedance 22
- 2.1.2 Potential Coefficient 25
- 2.2 Pipe-enclosed Type Cable (PT Cable) 27
- 2.2.1 Impedance 27
- 2.2.2 Potential Coefficient 29
- 2.3 Arbitrary Cross-section Conductor 31
- 2.3.1 Equivalent Cylindrical Conductor 31
- 2.3.2 Examples 32
- 2.4 Semiconducting Layer Impedance 35
- 2.4.1 Derivation of Impedance 35
- 2.4.2 Impedance of Two-layered Conductor 38
- 2.4.3 Discussion of the Impedance Formula 38
- 2.4.4 Admittance of Semiconducting Layer 40
- 2.4.5 Wave Propagation Characteristic of Cable with Core Outer Semiconducting Layer 40
- 2.4.6 Concluding Remarks 47
- 2.5 Discussion of the Formulation 47
- 2.5.1 Discussion of the Formulas 47
- 2.5.2 Parameters Influencing Cable Impedance and Admittance 49
- 2.6 EMTP Subroutines (3z (BCable Constants (3y (B and (3z (BCable Parameters (3y (B 52
- 2.6.1 Overhead Line 52
- 2.6.2 Underground/Overhead Cable 52
- Appendix 2.A Impedance of an SC Cable Consisting of a Core, a Sheath and an Armor 54
- Appendix 2.B Potential Coefficient 56
- Appendix 2.C Internal Impedances of Arbitrary Cross-section Conductor 57
- Appendix 2.D Derivation of Semiconducting Layer Impedance 58
- References 61
- 3 Theory of Wave Propagation in Cables 63 /Akihiro Ametani
- 3.1 Modal Theory 63
- 3.1.1 Eigenvalues and Vectors 63
- 3.1.2 Calculation of a Matrix Function by Eigenvalues/Vectors 65
- 3.1.3 Direct Application of Eigenvalue Theory to a Multi-conductor System 66.
- 3.1.4 Modal Theory 67
- 3.1.5 Formulation of Multi-conductor Voltages and Currents 69
- 3.1.6 Boundary Conditions and Two-port Theory 71
- 3.1.7 Problems 77
- 3.2 Basic Characteristics of Wave Propagation on Single-phase SC Cables 78
- 3.2.1 Basic Propagation Characteristics for a Transient 78
- 3.2.2 Frequency-dependent Characteristics 81
- 3.2.3 Time Response of Wave Deformation 84
- 3.3 Three-phase Underground SC Cables 84
- 3.3.1 Mutual Coupling between Phases 84
- 3.3.2 Transformation Matrix 86
- 3.3.3 Attenuation and Velocity 87
- 3.3.4 Characteristic Impedance 88
- 3.4 Effect of Various Parameters of an SC Cable 90
- 3.4.1 Buried Depth h 91
- 3.4.2 Earth Resistivity?e 91
- 3.4.3 Sheath Thickness d 91
- 3.4.4 Sheath Resistivity?s 91
- 3.4.5 Arrangement of a Three-phase SC Cable 93
- 3.5 Cross-bonded Cable 94
- 3.5.1 Introduction of Cross-bonded Cable 94
- 3.5.2 Theoretical Formulation of a Cross-bonded Cable 95
- 3.5.3 Homogeneous Model of a Cross-bonded Cable 102
- 3.5.4 Difference between Tunnel-installed and Buried Cables 105
- 3.6 PT Cable 114
- 3.6.1 Introduction of PT Cable 114
- 3.6.2 PT Cable with Finite-pipe Thickness 115
- 3.6.3 Effect of Eccentricity of Inner Conductor 128
- 3.6.4 Effect of the Permittivity of the Pipe Inner Insulator 133
- 3.6.5 Overhead PT Cable 133
- 3.7 Propagation Characteristics of Intersheath Modes 134
- 3.7.1 Theoretical Analysis of Intersheath Modes 134
- 3.7.2 Transients on a Cross-bonded Cable 144
- 3.7.3 Earth-return Mode 159
- 3.7.4 Concluding Remarks 160
- References 160
- 4 Cable Modeling for Transient Simulations 163 /Teruo Ohno and Akihiro Ametani
- 4.1 Sequence Impedances Using a Lumped PI-circuit Model 163
- 4.1.1 Solidly Bonded Cables 163
- 4.1.2 Cross-bonded Cables 167
- 4.1.3 Derivation of Sequence Impedance Formulas 168
- 4.2 Electromagnetic Transients Program (EMTP) Cable Models for Transient Simulations 174
- 4.3 Dommel Model 175
- 4.4 Semlyen Frequency-dependent Model 176.
- 4.4.1 Semlyen Model 177
- 4.4.2 Linear Model 178
- 4.5 Marti Model 178
- 4.6 Latest Frequency-dependent Models 179
- 4.6.1 Vector Fitting 179
- 4.6.2 Frequency Region Partitioning Algorithm 181
- References 182
- 5 Basic Characteristics of Transients on Single-phase Cables 185 /Akihiro Ametani
- 5.1 Single-core Coaxial (SC) Cable 185
- 5.1.1 Experimental Observations 185
- 5.1.2 EMTP Simulations 187
- 5.1.3 Theoretical Analysis 192
- 5.1.4 Analytical Evaluation of Parameters 203
- 5.1.5 Analytical Calculation of Transient Voltages 204
- 5.1.6 Concluding Remarks 211
- 5.2 Pipe-enclosed Type (PT) Cable-Effect of Eccentricity 212
- 5.2.1 Model Circuit for the EMTP Simulation 212
- 5.2.2 Simulation Results for Step-function Voltage Source 214
- 5.2.3 FDTD Simulation 218
- 5.2.4 Theoretical Analysis 218
- 5.2.5 Concluding Remarks 224
- 5.3 Effect of a Semiconducting Layer on a Transient 225
- 5.3.1 Step Function Voltage Applied to a 2 km Cable 225
- 5.3.2 5 x 70 (So (Bs Impulse Voltage Applied to a 40 km Cable 226
- References 227
- 6 Transient on Three-phase Cables in a Real System 229 /Akihiro Ametani
- 6.1 Cross-bonded Cable 229
- 6.1.1 Field Test on an 110 kV Oil-filled (OF) Cable 229
- 6.1.2 Effect of Cross-bonding 229
- 6.1.3 Effect of Various Parameters 232
- 6.1.4 Homogeneous Model (See Section 3.5.3) 237
- 6.1.5 PAI-circuit Model 239
- 6.2 Tunnel-installed 275 kV Cable 240
- 6.2.1 Cable Configuration 240
- 6.2.2 Effect of Geometrical Parameters on Wave Propagation 241
- 6.2.3 Field Test on 275 kV XLPE Cable 243
- 6.2.4 Concluding Remarks 249
- 6.3 Cable Installed Underneath a Bridge 252
- 6.3.1 Model System 252
- 6.3.2 Effect of an Overhead Cable and a Bridge 253
- 6.3.3 Effect of Overhead Lines on a Cable Transient 257
- 6.4 Cable Modeling in EMTP Simulations 262
- 6.4.1 Marti's and Dommel's Cable Models 262
- 6.4.2 Homogeneous Cable Model (See Section 3.5.3) 265
- 6.4.3 Effect of Tunnel-installed Cable 265
- 6.5 Pipe-enclosed Type (PT) Cable 266.
- 6.5.1 Field Test on a 275 kV Pressure Oil-filled (POF) Cable 266
- 6.5.2 Measured Results 267
- 6.5.3 FTP Simulation 269
- 6.6 Gas-insulated Substation (GIS)
- Overhead Cables 274
- 6.6.1 Basic Characteristic of an Overhead Cable 274
- 6.6.2 Effect of Spacer in a Bus 275
- 6.6.3 Three-phase Underground Gas-insulated Line 281
- 6.6.4 Switching Surges in a 500 kV GIS 282
- 6.6.5 Basic Characteristics of Switching Surges Induced to a Control Cable 284
- Appendix 6.A 293
- Appendix 6.B 295
- References 295
- 7 Examples of Cable System Transients 297 /Teruo Ohno
- 7.1 Reactive Power Compensation 297
- 7.2 Temporary Overvoltages 298
- 7.2.1 Series Resonance Overvoltage 298
- 7.2.2 Parallel Resonance Overvoltage 310
- 7.2.3 Overvoltage Caused by System Islanding 314
- 7.3 Slow-front Overvoltages 317
- 7.3.1 Line Energization Overvoltages from a Lumped Source 317
- 7.3.2 Line Energization Overvoltages from a Complex Source 329
- 7.3.3 Analysis of Statistical Distribution of Energization Overvoltages 332
- 7.4 Leading Current Interruption 341
- 7.5 Zero-missing Phenomenon 342
- 7.5.1 Zero-missing Phenomenon and Countermeasures 342
- 7.5.2 Sequential Switching 344
- 7.6 Cable Discharge 346
- References 347
- 8 Cable Transient in Distributed Generation System 351 /Naoto Nagaoka
- 8.1 Transient Simulation of Wind Farm 351
- 8.1.1 Circuit Diagram 351
- 8.1.2 Cable Model and Dominant Frequency 352
- 8.1.3 Data for Cable Parameters 354
- 8.1.4 EMTP Data Structure 359
- 8.1.5 Results of Pre-calculation 363
- 8.1.6 Cable Energization 364
- 8.2 Transients in a Solar Plant 374
- 8.2.1 Modeling of Solar Plant 374
- 8.2.2 Simulated Results 379
- References 388
- Index 391.