Design and Application of Modern Synchronous Generator Excitation Systems
Wiley-IEEE Press (Verlag)
978-1-118-84087-0 (ISBN)
This book systematically introduces the important technologies of design and application of the synchronous generator excitation system, including the three-phase bridge rectifier circuit, diode rectifier for separate excitation, brushless excitation system and the static self-stimulation excitation system. It fuses discussions on specific topics and basic theories, providing a detailed description of the theories essential for synchronous generators in the analysis of excitation systems.
Design and Application of Modern Synchronous Generator Excitation Systems provides a cutting-edge examination of excitation system, addressing conventional hydro-turbines, pumped storage units, steam turbines, and nuclear power units. It looks at the features and performance of the excitation system of the 700MW hydro-turbine deployed at the Three Gorges Hydropower Plant spanning the Yangtze River in China, as well as the working principle and start-up procedure of the static frequency converter (SFC) of pumped storage units. It also expounds on the composition of the excitation transformer, power rectifier, de-excitation equipment, and automatic excitation regulator—in addition to the performance features of the excitation system of conventional 600/1000MW turbines and the excitation system of the 1000MW nuclear power unit.
Presents cutting-edge technologies of the excitation system from a unique engineering perspective
Offers broad appeal to power system engineers who require a better understanding of excitation systems
Addresses hydro-turbines, pumped storage units, steam turbines, and nuclear power units
Provides an interdisciplinary examination of a range of applications
Written by a senior expert in the area of excitation systems
Written by an author with over 50 years' experience, Design and Application of Modern Synchronous Generator Excitation Systems is an excellent text that offers an interdisciplinary exposition for professionals, researchers, and academics alike.
Jicheng Li, Professor, is Senior Engineer and Consultant Research Fellow of the National Key Laboratory of Power Systems, Tsinghua University, China. He is one of the expert panel members for the excitation system bid evaluation for the major hydropower projects represented by the Three Gorges, Longtan, Jinghong, and Lawaxi hydropower plants in China.
About the Author xxi
Foreword xxiii
Preface xxvii
Introduction xxix
Acknowledgement xxxi
1 Evolution and Development of Excitation Control 1
1.1 Overview 1
1.2 Evolution of Excitation Control 1
1.3 Linear Multivariable Total Controller 11
1.4 Nonlinear Multivariable Excitation Controller 20
1.5 Power System Voltage Regulator (PSVR) 25
2 Characteristics of Synchronous Generator 35
2.1 Electromotive Force Phasor Diagram of Synchronous Generator 35
2.2 Electromagnetic Power and Power Angle Characteristic of Synchronous Generator 38
2.3 Operating Capacity Characteristic Curve of Synchronous Generator 41
2.4 Influence of External Reactance on Operating Capacity Characteristic Curve 45
2.5 Operating Characteristic Curves of Generator 50
2.6 Transient Characteristics of Synchronous Generator 54
3 Effect of Excitation Regulation on Power System Stability 67
3.1 Definition and Classification of Power System Stability 67
3.2 Criterion of Stability Level 68
3.3 Effects of Excitation Regulation on Power System Stability 68
4 Static and Transient State Characteristics of Excitation Systems 77
4.1 Static Characteristics of Excitation System 77
4.2 Ratio and Coefficient of Generator Voltage to Reactive Current of Generator 81
4.3 Transient State Characteristics of Excitation System 87
4.4 Stability Analysis of Excitation System 94
5 Control Law and Mathematical Model of Excitation System 97
5.1 Basic Control Law of Excitation System 97
5.2 Mathematical Model of the Excitation System 108
5.3 Mathematical Model of Excitation Control Unit 118
5.4 Parameter Setting of Excitation System 124
6 Basic Characteristics of Three-Phase Bridge Rectifier Circuit 137
6.1 Overview 137
6.2 Operating Principle of Three-Phase Bridge Rectifier 137
6.3 Type I Commutation State 139
6.4 Commutation Angle 144
6.5 Average Rectified Voltage 144
6.6 Instantaneous Rectified Voltage Value 147
6.7 Effective Element Current Value 147
6.8 Fundamental Wave and Harmonic Value for Alternating Current 152
6.9 Power Factor of Rectifying Device 156
6.10 Type III Commutation State 161
6.11 Type II Commutation State 167
6.12 External Characteristic Curve for Rectifier 168
6.13 Operating Principle of Three-Phase Bridge Inverter Circuit 170
7 Excitation System for Separately Excited Static Diode Rectifier 175
7.1 Harmonic Analysis for Alternating Current 175
7.2 Non-distortion Sinusoidal Potential and Equivalent Commutating Reactance 177
7.3 Expression for Commutation Angle γ, Load Resistance rf, and Commutating Reactance Xγ 182
7.4 Rectified Voltage Ratio 𝛽u and Rectified Current Ratio 𝛽i 184
7.5 Steady-State Calculations for AC Exciter with Rectifier Load 186
7.6 General External Characteristics of Exciter 189
7.7 Transient State Process of AC Exciter with Rectifier Load 191
7.8 Simplified Transient Mathematical Model of AC Exciter with Rectifier Load 193
7.9 Transient State Process of Excitation System in Case of Small Deviation Change in Generator Excitation Current 196
7.10 Influence of Diode Rectifier on Time Constant of Generator Excitation Loop 200
7.11 Excitation Voltage Response for AC Exciter with Rectifier Load 201
7.12 Short-Circuit Current Calculations for AC Exciter 205
7.13 Calculations for AC Rated Parameters and Forced Excitation Parameters 211
8 Brushless Excitation System 215
8.1 Evolution of Brushless Excitation System 215
8.2 Technical Specifications for Brushless Excitation System 219
8.3 Composition of Brushless Excitation System 221
8.4 Voltage Response Characteristics of AC Exciter 224
8.5 Control Characteristics of Brushless Excitation System 227
8.6 Mathematical Models for Brushless Excitation System 232
8.7 AC2 Model 243
8.8 Generator Excitation Parameter Detection and Fault Alarm 246
9 Separately Excited SCR Excitation System 255
9.1 Overview 255
9.2 Characteristics of Separately Excited SCR Excitation System 255
9.3 Influence of Harmonic Current Load on Electromagnetic Characteristics of Auxiliary Generator 260
9.4 Parameterization of Separately Excited SCR Excitation System 268
9.5 Separately Excited SCR Excitation System with High-/Low-Voltage Bridge Rectifier 272
9.6 Parameterization of High-/Low-Voltage Bridge Rectifier 276
9.7 Transient Process of Separately Excited SCR Excitation System 281
10 Static Self-Excitation System 285
10.1 Overview 285
10.2 Characteristics of Static Self-Excitation System 288
10.3 Shaft Voltage of Static Self-Excitation System 307
10.4 Coordination between Low Excitation Restriction and Loss-of-Excitation Protection 311
10.5 Electric Braking of Steam Turbine 321
10.6 Electric Braking Application Example at Pumped-Storage Power Station 326
11 Automatic Excitation Regulator 329
11.1 Overview 329
11.2 Theoretical Basis of Digital Control 330
11.3 Digital Sampling and Signal Conversion 337
11.4 Control Operation 340
11.5 Per-Unit Value Setting 345
11.6 Digital Phase Shift Trigger 346
11.7 External Characteristics of Three-Phase Fully Controlled Bridge Rectifier Circuit 348
11.8 Characteristics of Digital Excitation Systems 351
12 Excitation Transformer 365
12.1 Overview 365
12.2 Structural Characteristics of Resin Cast Dry-Type Excitation Transformer 367
12.3 Application Characteristics of Resin Cast Dry-Type Excitation Transformer 369
12.4 Specification for Resin Cast Dry-Type Excitation Transformer 369
12.5 Harmonic Current Analysis 389
13 Power Rectifier 395
13.1 Specification and Essential Parameters for Thyristor Rectifier Elements 395
13.2 Parameterization of Power Rectifier 400
13.3 Cooling of Large-Capacity Power Rectifier 407
13.4 Current Sharing of Power Rectifier 413
13.5 Protection of Power Rectifier 416
13.6 Thyristor Damage and Failure 429
13.7 Capacity of Power Rectifiers Operating in Parallel 433
13.8 Uncertainty of Parallel Operation of Double-Bridge Power Rectifiers 437
13.9 Five-Pole Disconnector of Power Rectifier 439
14 De-excitation and Rotor Overvoltage Protection of Synchronous Generator 441
14.1 Overview 441
14.2 Evaluation of Performance of De-excitation System 443
14.3 De-excitation System Classification 447
14.4 Influence of Saturation on De-excitation 463
14.5 Influence of Damping Winding Circuit on De-excitation 465
14.6 Field Circuit Breaker 467
14.7 Performance Characteristics of Nonlinear De-excitation Resistor 477
15 Excitation System Performance Characteristics of Hydropower Generator Set 485
15.1 Overview 485
15.2 Static Self-Excitation System of Xiangjiaba Hydro Power Station 485
16 Functional Characteristics of Excitation Control and Starting System of Reversible Pumped Storage Unit 521
16.1 Overview 521
16.2 Operation Mode and Excitation Control of Pumped Storage Unit 521
16.3 Application Example of Excitation System of Pumped Storage Unit 525
16.4 Working Principle of SFC 542
16.5 SFC Current and Speed Dual Closed-Loop Control System 560
16.6 Influence of SFC Start Current Harmonic Components on Power Station and Power System 562
16.7 Local Control Unit (LCU) Control Procedure for Pumped Storage Unit 566
16.8 Pumped Storage Unit Operating as Synchronous Condenser 568
16.9 De-excitation System of Pumped Storage Unit 569
16.10 Electric Braking of Pumped Storage Unit 572
16.11 Shaft Current Protection of Pumped Storage Unit 574
16.12 Application Characteristics of PSS of Pumped Storage Unit 577
17 Performance Characteristics of Excitation System of 1000 MW Turbine Generator Unit 579
17.1 Introduction of Excitation System of Turbine Generator of Malaysian Manjung 4 Thermal Power Station 579
17.2 Key Parameters of Turbine Generator Unit and Excitation System 581
17.3 Parameter Calculation of Main Components of Excitation System 585
17.4 Block Diagram of Automatically Regulated Excitation System 592
18 Performance Characteristics of 1000 MW Nuclear Power Steam Turbine Excitation System 601
18.1 Performance Characteristics of Steam Turbine Generator Brushless Excitation System of Fuqing Nuclear Power Station 601
18.2 Structural Characteristics of Brushless Excitation System 608
18.3 Analysis of Working State of Multi-Phase Brushless Exciter 612
18.4 Calculation of Excitation System Parameters of Fuqing Nuclear Power Station 618
18.5 Static Excitation System of Sanmen Nuclear Power Station 624
References 639
Index 643
| Erscheinungsdatum | 08.07.2019 |
|---|---|
| Sprache | englisch |
| Maße | 208 x 257 mm |
| Gewicht | 1452 g |
| Themenwelt | Technik ► Elektrotechnik / Energietechnik |
| ISBN-10 | 1-118-84087-9 / 1118840879 |
| ISBN-13 | 978-1-118-84087-0 / 9781118840870 |
| Zustand | Neuware |
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