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The comprehensive guide for large turbo-generator operation and maintenance
The Handbook of Large Turbo-Generator Operation and Maintenance is an expanded 3rd edition of the authors' second edition of the same book. This updated revision covers additional topics on generators and provides more depth on existing topics. It is the ultimate resource for operators and inspectors of large utility and industrial generating facilities who deal with multiple units of disparate size, origin, and vintage. The book is also an excellent learning tool for students, consulting and design engineers. It offers the complete scope of information regarding operation and maintenance of all types of turbine-driven generators found in the world.
Based on the authors' ver eighty combined years of generating station and design work experience, the information presented in the book is designed to inform the reader about actual machine operational problems and failure modes that occur in generating stations and other types of facilities. Readers will find very detailed coverage of:
* Design and construction of generators and auxiliary systems
* Generator operation and control, including interaction with the grid
* Monitoring, diagnostics, and protection of turbo-generators
* Inspection practices for the stator, rotor, and auxiliary systems
* Maintenance testing, including electrical and non-destructive examination
* Ideas on maintenance strategies and life cycle management
* Additional topics on uprating of generators and long term storage are also included
The Handbook of Large Turbo-Generator Operation and Maintenance comes packed with photos and graphs, commonly used inspection forms, and extensive references for each topic. It is an indispensable reference for anyone involved in the design, construction, operation, protection, maintenance, and troubleshooting of large generators in generating stations and industrial power facilities.
The Handbook of Large Turbo-Generator Operation and Maintenance is an expanded 3rd edition of the authors' second edition of the same book. This updated revision covers additional topics on generators and provides more depth on existing topics. It is the ultimate resource for operators and inspectors of large utility and industrial generating facilities who deal with multiple units of disparate size, origin, and vintage. The book is also an excellent learning tool for students, consulting and design engineers. It offers the complete scope of information regarding operation and maintenance of all types of turbine-driven generators found in the world.
Based on the authors' ver eighty combined years of generating station and design work experience, the information presented in the book is designed to inform the reader about actual machine operational problems and failure modes that occur in generating stations and other types of facilities. Readers will find very detailed coverage of:
* Design and construction of generators and auxiliary systems
* Generator operation and control, including interaction with the grid
* Monitoring, diagnostics, and protection of turbo-generators
* Inspection practices for the stator, rotor, and auxiliary systems
* Maintenance testing, including electrical and non-destructive examination
* Ideas on maintenance strategies and life cycle management
* Additional topics on uprating of generators and long term storage are also included
The Handbook of Large Turbo-Generator Operation and Maintenance comes packed with photos and graphs, commonly used inspection forms, and extensive references for each topic. It is an indispensable reference for anyone involved in the design, construction, operation, protection, maintenance, and troubleshooting of large generators in generating stations and industrial power facilities.
The comprehensive guide for large turbo-generator operation and maintenance
The Handbook of Large Turbo-Generator Operation and Maintenance is an expanded 3rd edition of the authors' second edition of the same book. This updated revision covers additional topics on generators and provides more depth on existing topics. It is the ultimate resource for operators and inspectors of large utility and industrial generating facilities who deal with multiple units of disparate size, origin, and vintage. The book is also an excellent learning tool for students, consulting and design engineers. It offers the complete scope of information regarding operation and maintenance of all types of turbine-driven generators found in the world.
Based on the authors' ver eighty combined years of generating station and design work experience, the information presented in the book is designed to inform the reader about actual machine operational problems and failure modes that occur in generating stations and other types of facilities. Readers will find very detailed coverage of:
* Design and construction of generators and auxiliary systems
* Generator operation and control, including interaction with the grid
* Monitoring, diagnostics, and protection of turbo-generators
* Inspection practices for the stator, rotor, and auxiliary systems
* Maintenance testing, including electrical and non-destructive examination
* Ideas on maintenance strategies and life cycle management
* Additional topics on uprating of generators and long term storage are also included
The Handbook of Large Turbo-Generator Operation and Maintenance comes packed with photos and graphs, commonly used inspection forms, and extensive references for each topic. It is an indispensable reference for anyone involved in the design, construction, operation, protection, maintenance, and troubleshooting of large generators in generating stations and industrial power facilities.
The Handbook of Large Turbo-Generator Operation and Maintenance is an expanded 3rd edition of the authors' second edition of the same book. This updated revision covers additional topics on generators and provides more depth on existing topics. It is the ultimate resource for operators and inspectors of large utility and industrial generating facilities who deal with multiple units of disparate size, origin, and vintage. The book is also an excellent learning tool for students, consulting and design engineers. It offers the complete scope of information regarding operation and maintenance of all types of turbine-driven generators found in the world.
Based on the authors' ver eighty combined years of generating station and design work experience, the information presented in the book is designed to inform the reader about actual machine operational problems and failure modes that occur in generating stations and other types of facilities. Readers will find very detailed coverage of:
* Design and construction of generators and auxiliary systems
* Generator operation and control, including interaction with the grid
* Monitoring, diagnostics, and protection of turbo-generators
* Inspection practices for the stator, rotor, and auxiliary systems
* Maintenance testing, including electrical and non-destructive examination
* Ideas on maintenance strategies and life cycle management
* Additional topics on uprating of generators and long term storage are also included
The Handbook of Large Turbo-Generator Operation and Maintenance comes packed with photos and graphs, commonly used inspection forms, and extensive references for each topic. It is an indispensable reference for anyone involved in the design, construction, operation, protection, maintenance, and troubleshooting of large generators in generating stations and industrial power facilities.
Über den Autor
GEOFF KLEMPNER, BASc, is a large generator specialist, located in Toronto, Canada. He is an IEEE Fellow and has served on numerous IEEE committees and standards working groups for large generators and is also a contributor to CIGRE on large rotating electrical machines.
ISIDOR KERSZENBAUM, PHD, is an IEEE Fellow, located in Irvine, CA. He is a generator specialist consulting to power plants on operation, maintenance and trouble-shooting of large motors and generators.
Inhaltsverzeichnis
Preface xxi
Acknowledgments xxvii
I THEORY, CONSTRUCTION, AND OPERATION
1 PRINCIPLES OF OPERATION OF SYNCHRONOUS MACHINES 3
1.1 Introduction To Basic Notions On Electric Power 4
1.1.1 Magnetism and Electromagnetism 4
1.1.2 Electricity 7
1.2 Electrical-Mechanical Equivalence 8
1.3 Alternating Current (ac) 8
1.4 Three-Phase Circuits 20
1.5 Basic Principles of Machine Operation 22
1.5.1 Faraday's Law of Electromagnetic Induction 22
1.5.2 Ampere-Biot-Savart's Law of Electromagnetic-Induced Forces 22
1.5.3 Lenz's Law of Action and Reaction 23
1.5.4 Electromechanical Energy Conversion 24
1.6 The Synchronous Machine 26
1.6.1 Background 26
1.6.2 Principles of Construction 28
1.6.3 Rotor Windings 32
1.6.4 Stator Windings 34
1.7 Basic Operation of The Synchronous Machine 37
1.7.1 No-Load Operation 44
1.7.2 Motor Operation 46
1.7.3 Generator Operation 47
1.7.4 Equivalent Circuit 47
1.7.5 Machine Losses 50
Additional Reading 50
2 GENERATOR DESIGN AND CONSTRUCTION 53
2.1 Stator Core 55
2.1.1 General Construction Features 55
2.1.2 Insulated versus Noninsulated Cores 60
2.1.3 Cores Built with Consolidated "Donuts" 62
2.1.4 Robotic versus Hand Core Stacking 62
2.1.5 Core Stacking Pressure and Tightness 63
2.2 Stator Frame 64
2.2.1 General Construction Features 64
2.2.2 Caged Core Design 66
2.2.3 Grounding of Stator Frames 66
2.3 Flux and Armature Reaction 67
2.4 Electromagnetics 70
2.5 End-Region Effects and Flux Shielding 74
2.5.1 Stator Core-End Copper Flux Shields/Screens 75
2.5.2 Stator Core-End Flux Shunts 77
2.5.3 Combination Stator Core-End Flux Screens and Flux Shunts 78
2.5.4 Stator Core-End Packet Stepping 78
2.5.5 Stator Core-End Tooth Slitting 81
2.5.6 Keybar Shorting Straps 83
2.6 Stator Core and Frame Forces 84
2.7 Stator Windings 85
2.7.1 Stator Winding Configuration and Installation Overview 85
2.7.2 Overview of Stator Winding Design Considerations 89
2.7.3 Fundamental Concepts 93
2.7.4 Winding Structure 94
2.7.5 Winding Specific Layouts 95
2.7.6 Basic Formulae 96
2.7.7 Conductor Bar Construction 98
2.8 Stator Winding Wedges 111
2.9 End-Winding Support Systems 114
2.10 Stator Terminal Connections 117
2.11 Rotor Forging 118
2.12 Rotor Winding 124
2.13 Rotor Winding Slot Wedges 131
2.14 Amortisseur (Damper) Winding 133
2.15 Retaining Rings 133
2.16 Bore Copper and Terminal Connectors 143
2.17 Slip/collector Rings and Brush Gear 147
2.18 Rotor Couplings 149
2.19 Rotor Turning Gear 151
2.20 Bearings 152
2.21 Air and Hydrogen Cooling 152
2.21.1 Basic Cooling Arrangements 155
2.22 Rotor Fans 156
2.23 Hydrogen Containment 158
2.23.1 Journal-Type Hydrogen Seals 161
2.23.2 Thrust Collar-Type Hydrogen Seals 161
2.24 Hydrogen Coolers 162
2.25 Air Coolers 164
2.26 Water-Cooled Rotors 165
References 166
3 GENERATOR AUXILIARY SYSTEMS 169
3.1 Lube-Oil System 170
3.2 Hydrogen Cooling System 170
3.3 Seal-Oil System 173
3.4 Stator Cooling Water System 176
3.4.1 System Components 177
3.4.2 Stator Cooling Water Chemistry 180
3.4.3 Stator Cooling Water System Conditions 185
3.5 Exciter Systems 187
3.5.1 Types of Excitation Systems 187
3.5.2 Excitation System Performance Characteristics 192
3.5.3 Field Discharge Resistor 193
3.5.4 Automatic Voltage Regulator 196
3.5.5 Power System Stabilizer 198
4 OPERATION AND CONTROL 201
4.1 Basic Operating Parameters 202
4.1.1 Machine Rating 202
4.1.2 Apparent Power 203
4.1.3 Power Factor 205
4.1.4 Real Power 208
4.1.5 Reactive Power 209
4.1.6 Terminal Voltage 210
4.1.7 Stator Current 210
4.1.8 Field Voltage 212
4.1.9 Field Current 212
4.1.10 Speed 212
4.1.11 Hydrogen Pressure 212
4.1.12 Hydrogen Temperature 213
4.1.13 Short-Circuit Ratio 214
4.1.14 Volts Per Hertz and Overfluxing Events 214
4.2 Operating Modes 221
4.2.1 Shutdown 221
4.2.2 Turning Gear 222
4.2.3 Run-Up and Run-Down 224
4.2.4 Field Applied Off-Line (Open Circuit) 226
4.2.5 Synchronized and Loaded (Online) 226
4.2.6 Start-Up Operation 227
4.2.7 Online Operation 228
4.3 Machine Curves 229
4.3.1 Open-Circuit Saturation Characteristic 229
4.3.2 Short-Circuit Characteristic 229
4.3.3 Capability Curves 229
4.3.4 V-Curves 235
4.4 Special Operating Conditions 237
4.4.1 Unexcited Operation ("Loss-of-Field" Condition) 237
4.4.2 Negative-Sequence Currents 241
4.4.3 Off-Frequency Currents 242
4.4.4 Load Cycling and Repetitive Starts 243
4.4.5 Overloading 244
4.4.6 Extended Turning Gear Operation 245
4.4.7 Loss of Cooling 247
4.4.8 Overfluxing 248
4.4.9 Overspeed 256
4.4.10 Loss of Lubrication Oil 256
4.4.11 Out-of-Step Synchronization and "Near" Short Circuits 257
4.4.12 Ingression of Cooling Water and Lubricating Oil 259
4.4.13 Under- and Overfrequency Operation (U/F and O/F) 259
4.4.14 Brushes Bouncing Off the Sliprings due to Eccentricity and/or Vibration 261
4.5 Basic Operation Concepts 263
4.5.1 Steady-State Operation 263
4.5.2 Equivalent Circuit and Vector Diagram 264
4.5.3 Power Transfer Equations 264
4.5.4 Working with the Fundamental Circuit Equation 270
4.5.5 Parallel Operation of Generators 273
4.5.6 Stability 276
4.5.7 Sudden Short Circuits 290
4.6 System Considerations 291
4.6.1 Voltage and Frequency Variation 292
4.6.2 Negative-Sequence Current 292
4.6.3 Overcurrent 302
4.6.4 Current Transients 302
4.6.5 Overspeed 303
4.7 Grid-Induced Torsional Vibrations 303
4.7.1 Basic Principles of Shaft Torsional Vibration 303
4.7.2 Spring Model of a Turbo-Generator Shaft Train 305
4.7.3 Determination of Shaft Torque and Shaft Torsional Stress 308
4.7.4 Material Changes Due to Torsional Vibrations 308
4.7.5 Types of Grid-Induced Events 308
4.7.6 Monitoring of Torsional Vibration Events 315
4.7.7 Industry Experience and Alleviation Techniques 315
4.8 Excitation and Voltage Regulation 316
4.8.1 The Exciter 316
4.8.2 Excitation Control 317
4.9 Performance Curves 318
4.9.1 Loss Curves 318
4.9.2 Efficiency Curves 319
4.10 Sample of Generator Operating Instructions 319
References 330
5 MONITORING AND DIAGNOSTICS 331
5.1 Generator Monitoring Philosophies 332
5.2 Monitoring Versus Protection: Definition and Practice 333
5.3 Extent of Monitoring Versus Cost and Benefits 335
5.4 Simple Monitoring With Static High-Level Alarm Limits 335
5.5 Dynamic Monitoring With Load-Varying Alarm Limits 336
5.6 Artificial Intelligence Diagnostic Systems 342
5.7 Monitoring A Single Parameter Versus A Multifunction Instrument 345
5.8 Monitored Parameters 346
5.8.1 Generator Electrical Parameters 347
5.8.2 Stator Core and Frame 352
5.8.3 Stator Winding 364
5.8.4 Rotor 391
5.8.5 Excitation System 409
5.8.6 Hydrogen Cooling System 410
5.8.7 Lube-Oil System 415
5.8.8 Seal-Oil System 418
5.8.9 Stator Cooling Water System 421
References 427
6 GENERATOR PROTECTION 429
6.1 Basic Protection Philosophy 429
6.2 Generator Protective Functions 431
6.2.1 Protection Alarm Response 434
6.2.2 Protection Trip Response 435
6.3 Brief Description of Protective Functions 435
6.3.1 Synchronizer and Sync-Check Relays (Functions 15 and 25) 436
6.3.2 Short-Circuit Protection (Functions 21, 50, 51, 51V, and 87) 436
6.3.3 Volts/Hertz Protection (Function 24) 439
6.3.4 Over- and Undervoltage Protection (Functions 59 and 27) 443
6.3.5 Reverse Power Protection (Function 32) 443
6.3.6 Loss-of-Field Protection (Function 40) 445
6.3.7 Stator Unbalanced Current Protection (Function 46) 445
6.3.8 Stator and Rotor Thermal Protection (Function 49) 447
6.3.9 Voltage Balance Protection (Function 60) 448
6.3.10 Time Overcurrent Protection for Detection of Turn-to-Turn Faults (Function 61) 449
6.3.11 Breaker Failure Protection (Function 62B) 450
6.3.12 Rotor Ground-Fault Protection (Function 64F) 451
6.3.13 Stator Ground Fault Protection (Functions 27, 51, 59) 453
6.3.14 Stator Ground Fault Protection Utilizing Third Harmonic-Based Relays 454
6.3.15 Stator Ground Fault Protection by Low-Frequency Injection 455
6.3.16 Over-/Underfrequency Protection (Function 81) 455
6.3.17 Out-of-Step Operation (Loss of Synchronism, Function 78) 456
6.4 Specialized Protection Schemes 457
6.4.1 Protection against Accidental Energization 457
6.4.2 dc Field Ground Discrimination 459
6.4.3 Vibration Considerations 462
6.4.4 Operation of the Isolated-Phase Bus (IPB) at Reduced Cooling and Risks from H2 Leaks into the IPB 463
6.4.5 Calculation of the H2-Air Mixture in the IPB for a Given H2 Leak from the Generator into the IPB 465
6.4.6 Calculation of Stator and Rotor Amortisseur Motoring Currents 472
6.4.7 Numerical Example for Calculating Rotor Amortisseur Motoring Currents 474
6.4.8 Voltage Across Field Terminals During an Induction Motoring or Generation Event 474
6.5 Tripping and Alarming Methods 475
References 477
II INSPECTION, MAINTENANCE, AND TESTING
7 INSPECTION PRACTICES AND METHODOLOGY 481
7.1 Site Preparation 481
7.1.1 Foreign Material Exclusion 481
7.1.2 Foreign Material Exclusion: Procedures 487
7.2 Experience and Training 490
7.3 Safety Procedures 491
7.3.1 Mechanical Obstacle Avoidance and Electrical Clearances 491
7.3.2 Confined Space Entry 495
7.3.3 Plan for Emergency Extraction 496
7.4 Inspection Frequency 496
7.5 Generator Accessibility 497
7.6 Inspection Tools 499
7.7 Inspection Forms 505
References 520
8 STATOR INSPECTION 521
8.1 Stator Frame and Casing 522
8.1.1 External Components 522
8.1.2 Internal Components 536
8.1.3 Caged Stator Cores-Inspection and Removal 547
8.2 Stator Core 549
8.2.1 Stator Bore Contamination 549
8.2.2 Blocked Cooling Vent Ducts 552
8.2.3 Iron Oxide Deposits 553
8.2.4 Loose Core Iron/Fretting and Interlaminar Failures 555
8.2.5 Bent/Broken Laminations in the Bore 571
8.2.6 Space Block Support and Migration 572
8.2.7 Migration of Broken Core Plate and Space Block Thick Plates 573
8.2.8 Laminations Bulging into Air Vents 574
8.2.9 Greasing/Oxide Deposits on Core Bolts 575
8.2.10 Core-Compression Plates 577
8.2.11 Core-End Flux Screens...
Acknowledgments xxvii
I THEORY, CONSTRUCTION, AND OPERATION
1 PRINCIPLES OF OPERATION OF SYNCHRONOUS MACHINES 3
1.1 Introduction To Basic Notions On Electric Power 4
1.1.1 Magnetism and Electromagnetism 4
1.1.2 Electricity 7
1.2 Electrical-Mechanical Equivalence 8
1.3 Alternating Current (ac) 8
1.4 Three-Phase Circuits 20
1.5 Basic Principles of Machine Operation 22
1.5.1 Faraday's Law of Electromagnetic Induction 22
1.5.2 Ampere-Biot-Savart's Law of Electromagnetic-Induced Forces 22
1.5.3 Lenz's Law of Action and Reaction 23
1.5.4 Electromechanical Energy Conversion 24
1.6 The Synchronous Machine 26
1.6.1 Background 26
1.6.2 Principles of Construction 28
1.6.3 Rotor Windings 32
1.6.4 Stator Windings 34
1.7 Basic Operation of The Synchronous Machine 37
1.7.1 No-Load Operation 44
1.7.2 Motor Operation 46
1.7.3 Generator Operation 47
1.7.4 Equivalent Circuit 47
1.7.5 Machine Losses 50
Additional Reading 50
2 GENERATOR DESIGN AND CONSTRUCTION 53
2.1 Stator Core 55
2.1.1 General Construction Features 55
2.1.2 Insulated versus Noninsulated Cores 60
2.1.3 Cores Built with Consolidated "Donuts" 62
2.1.4 Robotic versus Hand Core Stacking 62
2.1.5 Core Stacking Pressure and Tightness 63
2.2 Stator Frame 64
2.2.1 General Construction Features 64
2.2.2 Caged Core Design 66
2.2.3 Grounding of Stator Frames 66
2.3 Flux and Armature Reaction 67
2.4 Electromagnetics 70
2.5 End-Region Effects and Flux Shielding 74
2.5.1 Stator Core-End Copper Flux Shields/Screens 75
2.5.2 Stator Core-End Flux Shunts 77
2.5.3 Combination Stator Core-End Flux Screens and Flux Shunts 78
2.5.4 Stator Core-End Packet Stepping 78
2.5.5 Stator Core-End Tooth Slitting 81
2.5.6 Keybar Shorting Straps 83
2.6 Stator Core and Frame Forces 84
2.7 Stator Windings 85
2.7.1 Stator Winding Configuration and Installation Overview 85
2.7.2 Overview of Stator Winding Design Considerations 89
2.7.3 Fundamental Concepts 93
2.7.4 Winding Structure 94
2.7.5 Winding Specific Layouts 95
2.7.6 Basic Formulae 96
2.7.7 Conductor Bar Construction 98
2.8 Stator Winding Wedges 111
2.9 End-Winding Support Systems 114
2.10 Stator Terminal Connections 117
2.11 Rotor Forging 118
2.12 Rotor Winding 124
2.13 Rotor Winding Slot Wedges 131
2.14 Amortisseur (Damper) Winding 133
2.15 Retaining Rings 133
2.16 Bore Copper and Terminal Connectors 143
2.17 Slip/collector Rings and Brush Gear 147
2.18 Rotor Couplings 149
2.19 Rotor Turning Gear 151
2.20 Bearings 152
2.21 Air and Hydrogen Cooling 152
2.21.1 Basic Cooling Arrangements 155
2.22 Rotor Fans 156
2.23 Hydrogen Containment 158
2.23.1 Journal-Type Hydrogen Seals 161
2.23.2 Thrust Collar-Type Hydrogen Seals 161
2.24 Hydrogen Coolers 162
2.25 Air Coolers 164
2.26 Water-Cooled Rotors 165
References 166
3 GENERATOR AUXILIARY SYSTEMS 169
3.1 Lube-Oil System 170
3.2 Hydrogen Cooling System 170
3.3 Seal-Oil System 173
3.4 Stator Cooling Water System 176
3.4.1 System Components 177
3.4.2 Stator Cooling Water Chemistry 180
3.4.3 Stator Cooling Water System Conditions 185
3.5 Exciter Systems 187
3.5.1 Types of Excitation Systems 187
3.5.2 Excitation System Performance Characteristics 192
3.5.3 Field Discharge Resistor 193
3.5.4 Automatic Voltage Regulator 196
3.5.5 Power System Stabilizer 198
4 OPERATION AND CONTROL 201
4.1 Basic Operating Parameters 202
4.1.1 Machine Rating 202
4.1.2 Apparent Power 203
4.1.3 Power Factor 205
4.1.4 Real Power 208
4.1.5 Reactive Power 209
4.1.6 Terminal Voltage 210
4.1.7 Stator Current 210
4.1.8 Field Voltage 212
4.1.9 Field Current 212
4.1.10 Speed 212
4.1.11 Hydrogen Pressure 212
4.1.12 Hydrogen Temperature 213
4.1.13 Short-Circuit Ratio 214
4.1.14 Volts Per Hertz and Overfluxing Events 214
4.2 Operating Modes 221
4.2.1 Shutdown 221
4.2.2 Turning Gear 222
4.2.3 Run-Up and Run-Down 224
4.2.4 Field Applied Off-Line (Open Circuit) 226
4.2.5 Synchronized and Loaded (Online) 226
4.2.6 Start-Up Operation 227
4.2.7 Online Operation 228
4.3 Machine Curves 229
4.3.1 Open-Circuit Saturation Characteristic 229
4.3.2 Short-Circuit Characteristic 229
4.3.3 Capability Curves 229
4.3.4 V-Curves 235
4.4 Special Operating Conditions 237
4.4.1 Unexcited Operation ("Loss-of-Field" Condition) 237
4.4.2 Negative-Sequence Currents 241
4.4.3 Off-Frequency Currents 242
4.4.4 Load Cycling and Repetitive Starts 243
4.4.5 Overloading 244
4.4.6 Extended Turning Gear Operation 245
4.4.7 Loss of Cooling 247
4.4.8 Overfluxing 248
4.4.9 Overspeed 256
4.4.10 Loss of Lubrication Oil 256
4.4.11 Out-of-Step Synchronization and "Near" Short Circuits 257
4.4.12 Ingression of Cooling Water and Lubricating Oil 259
4.4.13 Under- and Overfrequency Operation (U/F and O/F) 259
4.4.14 Brushes Bouncing Off the Sliprings due to Eccentricity and/or Vibration 261
4.5 Basic Operation Concepts 263
4.5.1 Steady-State Operation 263
4.5.2 Equivalent Circuit and Vector Diagram 264
4.5.3 Power Transfer Equations 264
4.5.4 Working with the Fundamental Circuit Equation 270
4.5.5 Parallel Operation of Generators 273
4.5.6 Stability 276
4.5.7 Sudden Short Circuits 290
4.6 System Considerations 291
4.6.1 Voltage and Frequency Variation 292
4.6.2 Negative-Sequence Current 292
4.6.3 Overcurrent 302
4.6.4 Current Transients 302
4.6.5 Overspeed 303
4.7 Grid-Induced Torsional Vibrations 303
4.7.1 Basic Principles of Shaft Torsional Vibration 303
4.7.2 Spring Model of a Turbo-Generator Shaft Train 305
4.7.3 Determination of Shaft Torque and Shaft Torsional Stress 308
4.7.4 Material Changes Due to Torsional Vibrations 308
4.7.5 Types of Grid-Induced Events 308
4.7.6 Monitoring of Torsional Vibration Events 315
4.7.7 Industry Experience and Alleviation Techniques 315
4.8 Excitation and Voltage Regulation 316
4.8.1 The Exciter 316
4.8.2 Excitation Control 317
4.9 Performance Curves 318
4.9.1 Loss Curves 318
4.9.2 Efficiency Curves 319
4.10 Sample of Generator Operating Instructions 319
References 330
5 MONITORING AND DIAGNOSTICS 331
5.1 Generator Monitoring Philosophies 332
5.2 Monitoring Versus Protection: Definition and Practice 333
5.3 Extent of Monitoring Versus Cost and Benefits 335
5.4 Simple Monitoring With Static High-Level Alarm Limits 335
5.5 Dynamic Monitoring With Load-Varying Alarm Limits 336
5.6 Artificial Intelligence Diagnostic Systems 342
5.7 Monitoring A Single Parameter Versus A Multifunction Instrument 345
5.8 Monitored Parameters 346
5.8.1 Generator Electrical Parameters 347
5.8.2 Stator Core and Frame 352
5.8.3 Stator Winding 364
5.8.4 Rotor 391
5.8.5 Excitation System 409
5.8.6 Hydrogen Cooling System 410
5.8.7 Lube-Oil System 415
5.8.8 Seal-Oil System 418
5.8.9 Stator Cooling Water System 421
References 427
6 GENERATOR PROTECTION 429
6.1 Basic Protection Philosophy 429
6.2 Generator Protective Functions 431
6.2.1 Protection Alarm Response 434
6.2.2 Protection Trip Response 435
6.3 Brief Description of Protective Functions 435
6.3.1 Synchronizer and Sync-Check Relays (Functions 15 and 25) 436
6.3.2 Short-Circuit Protection (Functions 21, 50, 51, 51V, and 87) 436
6.3.3 Volts/Hertz Protection (Function 24) 439
6.3.4 Over- and Undervoltage Protection (Functions 59 and 27) 443
6.3.5 Reverse Power Protection (Function 32) 443
6.3.6 Loss-of-Field Protection (Function 40) 445
6.3.7 Stator Unbalanced Current Protection (Function 46) 445
6.3.8 Stator and Rotor Thermal Protection (Function 49) 447
6.3.9 Voltage Balance Protection (Function 60) 448
6.3.10 Time Overcurrent Protection for Detection of Turn-to-Turn Faults (Function 61) 449
6.3.11 Breaker Failure Protection (Function 62B) 450
6.3.12 Rotor Ground-Fault Protection (Function 64F) 451
6.3.13 Stator Ground Fault Protection (Functions 27, 51, 59) 453
6.3.14 Stator Ground Fault Protection Utilizing Third Harmonic-Based Relays 454
6.3.15 Stator Ground Fault Protection by Low-Frequency Injection 455
6.3.16 Over-/Underfrequency Protection (Function 81) 455
6.3.17 Out-of-Step Operation (Loss of Synchronism, Function 78) 456
6.4 Specialized Protection Schemes 457
6.4.1 Protection against Accidental Energization 457
6.4.2 dc Field Ground Discrimination 459
6.4.3 Vibration Considerations 462
6.4.4 Operation of the Isolated-Phase Bus (IPB) at Reduced Cooling and Risks from H2 Leaks into the IPB 463
6.4.5 Calculation of the H2-Air Mixture in the IPB for a Given H2 Leak from the Generator into the IPB 465
6.4.6 Calculation of Stator and Rotor Amortisseur Motoring Currents 472
6.4.7 Numerical Example for Calculating Rotor Amortisseur Motoring Currents 474
6.4.8 Voltage Across Field Terminals During an Induction Motoring or Generation Event 474
6.5 Tripping and Alarming Methods 475
References 477
II INSPECTION, MAINTENANCE, AND TESTING
7 INSPECTION PRACTICES AND METHODOLOGY 481
7.1 Site Preparation 481
7.1.1 Foreign Material Exclusion 481
7.1.2 Foreign Material Exclusion: Procedures 487
7.2 Experience and Training 490
7.3 Safety Procedures 491
7.3.1 Mechanical Obstacle Avoidance and Electrical Clearances 491
7.3.2 Confined Space Entry 495
7.3.3 Plan for Emergency Extraction 496
7.4 Inspection Frequency 496
7.5 Generator Accessibility 497
7.6 Inspection Tools 499
7.7 Inspection Forms 505
References 520
8 STATOR INSPECTION 521
8.1 Stator Frame and Casing 522
8.1.1 External Components 522
8.1.2 Internal Components 536
8.1.3 Caged Stator Cores-Inspection and Removal 547
8.2 Stator Core 549
8.2.1 Stator Bore Contamination 549
8.2.2 Blocked Cooling Vent Ducts 552
8.2.3 Iron Oxide Deposits 553
8.2.4 Loose Core Iron/Fretting and Interlaminar Failures 555
8.2.5 Bent/Broken Laminations in the Bore 571
8.2.6 Space Block Support and Migration 572
8.2.7 Migration of Broken Core Plate and Space Block Thick Plates 573
8.2.8 Laminations Bulging into Air Vents 574
8.2.9 Greasing/Oxide Deposits on Core Bolts 575
8.2.10 Core-Compression Plates 577
8.2.11 Core-End Flux Screens...
Details
| Erscheinungsjahr: | 2018 |
|---|---|
| Fachbereich: | Kraftwerktechnik |
| Genre: | Technik |
| Rubrik: | Naturwissenschaften & Technik |
| Medium: | Buch |
| Seiten: | 1040 |
| Inhalt: | 1040 S. |
| ISBN-13: | 9781119389767 |
| ISBN-10: | 1119389763 |
| Sprache: | Englisch |
| Einband: | Gebunden |
| Autor: |
Klempner, Geoff
Kerszenbaum, Isidor |
| Auflage: | 3rd edition |
| Hersteller: | Wiley |
| Maße: | 231 x 157 x 43 mm |
| Von/Mit: | Geoff Klempner (u. a.) |
| Erscheinungsdatum: | 07.08.2018 |
| Gewicht: | 1,356 kg |
Über den Autor
GEOFF KLEMPNER, BASc, is a large generator specialist, located in Toronto, Canada. He is an IEEE Fellow and has served on numerous IEEE committees and standards working groups for large generators and is also a contributor to CIGRE on large rotating electrical machines.
ISIDOR KERSZENBAUM, PHD, is an IEEE Fellow, located in Irvine, CA. He is a generator specialist consulting to power plants on operation, maintenance and trouble-shooting of large motors and generators.
Inhaltsverzeichnis
Preface xxi
Acknowledgments xxvii
I THEORY, CONSTRUCTION, AND OPERATION
1 PRINCIPLES OF OPERATION OF SYNCHRONOUS MACHINES 3
1.1 Introduction To Basic Notions On Electric Power 4
1.1.1 Magnetism and Electromagnetism 4
1.1.2 Electricity 7
1.2 Electrical-Mechanical Equivalence 8
1.3 Alternating Current (ac) 8
1.4 Three-Phase Circuits 20
1.5 Basic Principles of Machine Operation 22
1.5.1 Faraday's Law of Electromagnetic Induction 22
1.5.2 Ampere-Biot-Savart's Law of Electromagnetic-Induced Forces 22
1.5.3 Lenz's Law of Action and Reaction 23
1.5.4 Electromechanical Energy Conversion 24
1.6 The Synchronous Machine 26
1.6.1 Background 26
1.6.2 Principles of Construction 28
1.6.3 Rotor Windings 32
1.6.4 Stator Windings 34
1.7 Basic Operation of The Synchronous Machine 37
1.7.1 No-Load Operation 44
1.7.2 Motor Operation 46
1.7.3 Generator Operation 47
1.7.4 Equivalent Circuit 47
1.7.5 Machine Losses 50
Additional Reading 50
2 GENERATOR DESIGN AND CONSTRUCTION 53
2.1 Stator Core 55
2.1.1 General Construction Features 55
2.1.2 Insulated versus Noninsulated Cores 60
2.1.3 Cores Built with Consolidated "Donuts" 62
2.1.4 Robotic versus Hand Core Stacking 62
2.1.5 Core Stacking Pressure and Tightness 63
2.2 Stator Frame 64
2.2.1 General Construction Features 64
2.2.2 Caged Core Design 66
2.2.3 Grounding of Stator Frames 66
2.3 Flux and Armature Reaction 67
2.4 Electromagnetics 70
2.5 End-Region Effects and Flux Shielding 74
2.5.1 Stator Core-End Copper Flux Shields/Screens 75
2.5.2 Stator Core-End Flux Shunts 77
2.5.3 Combination Stator Core-End Flux Screens and Flux Shunts 78
2.5.4 Stator Core-End Packet Stepping 78
2.5.5 Stator Core-End Tooth Slitting 81
2.5.6 Keybar Shorting Straps 83
2.6 Stator Core and Frame Forces 84
2.7 Stator Windings 85
2.7.1 Stator Winding Configuration and Installation Overview 85
2.7.2 Overview of Stator Winding Design Considerations 89
2.7.3 Fundamental Concepts 93
2.7.4 Winding Structure 94
2.7.5 Winding Specific Layouts 95
2.7.6 Basic Formulae 96
2.7.7 Conductor Bar Construction 98
2.8 Stator Winding Wedges 111
2.9 End-Winding Support Systems 114
2.10 Stator Terminal Connections 117
2.11 Rotor Forging 118
2.12 Rotor Winding 124
2.13 Rotor Winding Slot Wedges 131
2.14 Amortisseur (Damper) Winding 133
2.15 Retaining Rings 133
2.16 Bore Copper and Terminal Connectors 143
2.17 Slip/collector Rings and Brush Gear 147
2.18 Rotor Couplings 149
2.19 Rotor Turning Gear 151
2.20 Bearings 152
2.21 Air and Hydrogen Cooling 152
2.21.1 Basic Cooling Arrangements 155
2.22 Rotor Fans 156
2.23 Hydrogen Containment 158
2.23.1 Journal-Type Hydrogen Seals 161
2.23.2 Thrust Collar-Type Hydrogen Seals 161
2.24 Hydrogen Coolers 162
2.25 Air Coolers 164
2.26 Water-Cooled Rotors 165
References 166
3 GENERATOR AUXILIARY SYSTEMS 169
3.1 Lube-Oil System 170
3.2 Hydrogen Cooling System 170
3.3 Seal-Oil System 173
3.4 Stator Cooling Water System 176
3.4.1 System Components 177
3.4.2 Stator Cooling Water Chemistry 180
3.4.3 Stator Cooling Water System Conditions 185
3.5 Exciter Systems 187
3.5.1 Types of Excitation Systems 187
3.5.2 Excitation System Performance Characteristics 192
3.5.3 Field Discharge Resistor 193
3.5.4 Automatic Voltage Regulator 196
3.5.5 Power System Stabilizer 198
4 OPERATION AND CONTROL 201
4.1 Basic Operating Parameters 202
4.1.1 Machine Rating 202
4.1.2 Apparent Power 203
4.1.3 Power Factor 205
4.1.4 Real Power 208
4.1.5 Reactive Power 209
4.1.6 Terminal Voltage 210
4.1.7 Stator Current 210
4.1.8 Field Voltage 212
4.1.9 Field Current 212
4.1.10 Speed 212
4.1.11 Hydrogen Pressure 212
4.1.12 Hydrogen Temperature 213
4.1.13 Short-Circuit Ratio 214
4.1.14 Volts Per Hertz and Overfluxing Events 214
4.2 Operating Modes 221
4.2.1 Shutdown 221
4.2.2 Turning Gear 222
4.2.3 Run-Up and Run-Down 224
4.2.4 Field Applied Off-Line (Open Circuit) 226
4.2.5 Synchronized and Loaded (Online) 226
4.2.6 Start-Up Operation 227
4.2.7 Online Operation 228
4.3 Machine Curves 229
4.3.1 Open-Circuit Saturation Characteristic 229
4.3.2 Short-Circuit Characteristic 229
4.3.3 Capability Curves 229
4.3.4 V-Curves 235
4.4 Special Operating Conditions 237
4.4.1 Unexcited Operation ("Loss-of-Field" Condition) 237
4.4.2 Negative-Sequence Currents 241
4.4.3 Off-Frequency Currents 242
4.4.4 Load Cycling and Repetitive Starts 243
4.4.5 Overloading 244
4.4.6 Extended Turning Gear Operation 245
4.4.7 Loss of Cooling 247
4.4.8 Overfluxing 248
4.4.9 Overspeed 256
4.4.10 Loss of Lubrication Oil 256
4.4.11 Out-of-Step Synchronization and "Near" Short Circuits 257
4.4.12 Ingression of Cooling Water and Lubricating Oil 259
4.4.13 Under- and Overfrequency Operation (U/F and O/F) 259
4.4.14 Brushes Bouncing Off the Sliprings due to Eccentricity and/or Vibration 261
4.5 Basic Operation Concepts 263
4.5.1 Steady-State Operation 263
4.5.2 Equivalent Circuit and Vector Diagram 264
4.5.3 Power Transfer Equations 264
4.5.4 Working with the Fundamental Circuit Equation 270
4.5.5 Parallel Operation of Generators 273
4.5.6 Stability 276
4.5.7 Sudden Short Circuits 290
4.6 System Considerations 291
4.6.1 Voltage and Frequency Variation 292
4.6.2 Negative-Sequence Current 292
4.6.3 Overcurrent 302
4.6.4 Current Transients 302
4.6.5 Overspeed 303
4.7 Grid-Induced Torsional Vibrations 303
4.7.1 Basic Principles of Shaft Torsional Vibration 303
4.7.2 Spring Model of a Turbo-Generator Shaft Train 305
4.7.3 Determination of Shaft Torque and Shaft Torsional Stress 308
4.7.4 Material Changes Due to Torsional Vibrations 308
4.7.5 Types of Grid-Induced Events 308
4.7.6 Monitoring of Torsional Vibration Events 315
4.7.7 Industry Experience and Alleviation Techniques 315
4.8 Excitation and Voltage Regulation 316
4.8.1 The Exciter 316
4.8.2 Excitation Control 317
4.9 Performance Curves 318
4.9.1 Loss Curves 318
4.9.2 Efficiency Curves 319
4.10 Sample of Generator Operating Instructions 319
References 330
5 MONITORING AND DIAGNOSTICS 331
5.1 Generator Monitoring Philosophies 332
5.2 Monitoring Versus Protection: Definition and Practice 333
5.3 Extent of Monitoring Versus Cost and Benefits 335
5.4 Simple Monitoring With Static High-Level Alarm Limits 335
5.5 Dynamic Monitoring With Load-Varying Alarm Limits 336
5.6 Artificial Intelligence Diagnostic Systems 342
5.7 Monitoring A Single Parameter Versus A Multifunction Instrument 345
5.8 Monitored Parameters 346
5.8.1 Generator Electrical Parameters 347
5.8.2 Stator Core and Frame 352
5.8.3 Stator Winding 364
5.8.4 Rotor 391
5.8.5 Excitation System 409
5.8.6 Hydrogen Cooling System 410
5.8.7 Lube-Oil System 415
5.8.8 Seal-Oil System 418
5.8.9 Stator Cooling Water System 421
References 427
6 GENERATOR PROTECTION 429
6.1 Basic Protection Philosophy 429
6.2 Generator Protective Functions 431
6.2.1 Protection Alarm Response 434
6.2.2 Protection Trip Response 435
6.3 Brief Description of Protective Functions 435
6.3.1 Synchronizer and Sync-Check Relays (Functions 15 and 25) 436
6.3.2 Short-Circuit Protection (Functions 21, 50, 51, 51V, and 87) 436
6.3.3 Volts/Hertz Protection (Function 24) 439
6.3.4 Over- and Undervoltage Protection (Functions 59 and 27) 443
6.3.5 Reverse Power Protection (Function 32) 443
6.3.6 Loss-of-Field Protection (Function 40) 445
6.3.7 Stator Unbalanced Current Protection (Function 46) 445
6.3.8 Stator and Rotor Thermal Protection (Function 49) 447
6.3.9 Voltage Balance Protection (Function 60) 448
6.3.10 Time Overcurrent Protection for Detection of Turn-to-Turn Faults (Function 61) 449
6.3.11 Breaker Failure Protection (Function 62B) 450
6.3.12 Rotor Ground-Fault Protection (Function 64F) 451
6.3.13 Stator Ground Fault Protection (Functions 27, 51, 59) 453
6.3.14 Stator Ground Fault Protection Utilizing Third Harmonic-Based Relays 454
6.3.15 Stator Ground Fault Protection by Low-Frequency Injection 455
6.3.16 Over-/Underfrequency Protection (Function 81) 455
6.3.17 Out-of-Step Operation (Loss of Synchronism, Function 78) 456
6.4 Specialized Protection Schemes 457
6.4.1 Protection against Accidental Energization 457
6.4.2 dc Field Ground Discrimination 459
6.4.3 Vibration Considerations 462
6.4.4 Operation of the Isolated-Phase Bus (IPB) at Reduced Cooling and Risks from H2 Leaks into the IPB 463
6.4.5 Calculation of the H2-Air Mixture in the IPB for a Given H2 Leak from the Generator into the IPB 465
6.4.6 Calculation of Stator and Rotor Amortisseur Motoring Currents 472
6.4.7 Numerical Example for Calculating Rotor Amortisseur Motoring Currents 474
6.4.8 Voltage Across Field Terminals During an Induction Motoring or Generation Event 474
6.5 Tripping and Alarming Methods 475
References 477
II INSPECTION, MAINTENANCE, AND TESTING
7 INSPECTION PRACTICES AND METHODOLOGY 481
7.1 Site Preparation 481
7.1.1 Foreign Material Exclusion 481
7.1.2 Foreign Material Exclusion: Procedures 487
7.2 Experience and Training 490
7.3 Safety Procedures 491
7.3.1 Mechanical Obstacle Avoidance and Electrical Clearances 491
7.3.2 Confined Space Entry 495
7.3.3 Plan for Emergency Extraction 496
7.4 Inspection Frequency 496
7.5 Generator Accessibility 497
7.6 Inspection Tools 499
7.7 Inspection Forms 505
References 520
8 STATOR INSPECTION 521
8.1 Stator Frame and Casing 522
8.1.1 External Components 522
8.1.2 Internal Components 536
8.1.3 Caged Stator Cores-Inspection and Removal 547
8.2 Stator Core 549
8.2.1 Stator Bore Contamination 549
8.2.2 Blocked Cooling Vent Ducts 552
8.2.3 Iron Oxide Deposits 553
8.2.4 Loose Core Iron/Fretting and Interlaminar Failures 555
8.2.5 Bent/Broken Laminations in the Bore 571
8.2.6 Space Block Support and Migration 572
8.2.7 Migration of Broken Core Plate and Space Block Thick Plates 573
8.2.8 Laminations Bulging into Air Vents 574
8.2.9 Greasing/Oxide Deposits on Core Bolts 575
8.2.10 Core-Compression Plates 577
8.2.11 Core-End Flux Screens...
Acknowledgments xxvii
I THEORY, CONSTRUCTION, AND OPERATION
1 PRINCIPLES OF OPERATION OF SYNCHRONOUS MACHINES 3
1.1 Introduction To Basic Notions On Electric Power 4
1.1.1 Magnetism and Electromagnetism 4
1.1.2 Electricity 7
1.2 Electrical-Mechanical Equivalence 8
1.3 Alternating Current (ac) 8
1.4 Three-Phase Circuits 20
1.5 Basic Principles of Machine Operation 22
1.5.1 Faraday's Law of Electromagnetic Induction 22
1.5.2 Ampere-Biot-Savart's Law of Electromagnetic-Induced Forces 22
1.5.3 Lenz's Law of Action and Reaction 23
1.5.4 Electromechanical Energy Conversion 24
1.6 The Synchronous Machine 26
1.6.1 Background 26
1.6.2 Principles of Construction 28
1.6.3 Rotor Windings 32
1.6.4 Stator Windings 34
1.7 Basic Operation of The Synchronous Machine 37
1.7.1 No-Load Operation 44
1.7.2 Motor Operation 46
1.7.3 Generator Operation 47
1.7.4 Equivalent Circuit 47
1.7.5 Machine Losses 50
Additional Reading 50
2 GENERATOR DESIGN AND CONSTRUCTION 53
2.1 Stator Core 55
2.1.1 General Construction Features 55
2.1.2 Insulated versus Noninsulated Cores 60
2.1.3 Cores Built with Consolidated "Donuts" 62
2.1.4 Robotic versus Hand Core Stacking 62
2.1.5 Core Stacking Pressure and Tightness 63
2.2 Stator Frame 64
2.2.1 General Construction Features 64
2.2.2 Caged Core Design 66
2.2.3 Grounding of Stator Frames 66
2.3 Flux and Armature Reaction 67
2.4 Electromagnetics 70
2.5 End-Region Effects and Flux Shielding 74
2.5.1 Stator Core-End Copper Flux Shields/Screens 75
2.5.2 Stator Core-End Flux Shunts 77
2.5.3 Combination Stator Core-End Flux Screens and Flux Shunts 78
2.5.4 Stator Core-End Packet Stepping 78
2.5.5 Stator Core-End Tooth Slitting 81
2.5.6 Keybar Shorting Straps 83
2.6 Stator Core and Frame Forces 84
2.7 Stator Windings 85
2.7.1 Stator Winding Configuration and Installation Overview 85
2.7.2 Overview of Stator Winding Design Considerations 89
2.7.3 Fundamental Concepts 93
2.7.4 Winding Structure 94
2.7.5 Winding Specific Layouts 95
2.7.6 Basic Formulae 96
2.7.7 Conductor Bar Construction 98
2.8 Stator Winding Wedges 111
2.9 End-Winding Support Systems 114
2.10 Stator Terminal Connections 117
2.11 Rotor Forging 118
2.12 Rotor Winding 124
2.13 Rotor Winding Slot Wedges 131
2.14 Amortisseur (Damper) Winding 133
2.15 Retaining Rings 133
2.16 Bore Copper and Terminal Connectors 143
2.17 Slip/collector Rings and Brush Gear 147
2.18 Rotor Couplings 149
2.19 Rotor Turning Gear 151
2.20 Bearings 152
2.21 Air and Hydrogen Cooling 152
2.21.1 Basic Cooling Arrangements 155
2.22 Rotor Fans 156
2.23 Hydrogen Containment 158
2.23.1 Journal-Type Hydrogen Seals 161
2.23.2 Thrust Collar-Type Hydrogen Seals 161
2.24 Hydrogen Coolers 162
2.25 Air Coolers 164
2.26 Water-Cooled Rotors 165
References 166
3 GENERATOR AUXILIARY SYSTEMS 169
3.1 Lube-Oil System 170
3.2 Hydrogen Cooling System 170
3.3 Seal-Oil System 173
3.4 Stator Cooling Water System 176
3.4.1 System Components 177
3.4.2 Stator Cooling Water Chemistry 180
3.4.3 Stator Cooling Water System Conditions 185
3.5 Exciter Systems 187
3.5.1 Types of Excitation Systems 187
3.5.2 Excitation System Performance Characteristics 192
3.5.3 Field Discharge Resistor 193
3.5.4 Automatic Voltage Regulator 196
3.5.5 Power System Stabilizer 198
4 OPERATION AND CONTROL 201
4.1 Basic Operating Parameters 202
4.1.1 Machine Rating 202
4.1.2 Apparent Power 203
4.1.3 Power Factor 205
4.1.4 Real Power 208
4.1.5 Reactive Power 209
4.1.6 Terminal Voltage 210
4.1.7 Stator Current 210
4.1.8 Field Voltage 212
4.1.9 Field Current 212
4.1.10 Speed 212
4.1.11 Hydrogen Pressure 212
4.1.12 Hydrogen Temperature 213
4.1.13 Short-Circuit Ratio 214
4.1.14 Volts Per Hertz and Overfluxing Events 214
4.2 Operating Modes 221
4.2.1 Shutdown 221
4.2.2 Turning Gear 222
4.2.3 Run-Up and Run-Down 224
4.2.4 Field Applied Off-Line (Open Circuit) 226
4.2.5 Synchronized and Loaded (Online) 226
4.2.6 Start-Up Operation 227
4.2.7 Online Operation 228
4.3 Machine Curves 229
4.3.1 Open-Circuit Saturation Characteristic 229
4.3.2 Short-Circuit Characteristic 229
4.3.3 Capability Curves 229
4.3.4 V-Curves 235
4.4 Special Operating Conditions 237
4.4.1 Unexcited Operation ("Loss-of-Field" Condition) 237
4.4.2 Negative-Sequence Currents 241
4.4.3 Off-Frequency Currents 242
4.4.4 Load Cycling and Repetitive Starts 243
4.4.5 Overloading 244
4.4.6 Extended Turning Gear Operation 245
4.4.7 Loss of Cooling 247
4.4.8 Overfluxing 248
4.4.9 Overspeed 256
4.4.10 Loss of Lubrication Oil 256
4.4.11 Out-of-Step Synchronization and "Near" Short Circuits 257
4.4.12 Ingression of Cooling Water and Lubricating Oil 259
4.4.13 Under- and Overfrequency Operation (U/F and O/F) 259
4.4.14 Brushes Bouncing Off the Sliprings due to Eccentricity and/or Vibration 261
4.5 Basic Operation Concepts 263
4.5.1 Steady-State Operation 263
4.5.2 Equivalent Circuit and Vector Diagram 264
4.5.3 Power Transfer Equations 264
4.5.4 Working with the Fundamental Circuit Equation 270
4.5.5 Parallel Operation of Generators 273
4.5.6 Stability 276
4.5.7 Sudden Short Circuits 290
4.6 System Considerations 291
4.6.1 Voltage and Frequency Variation 292
4.6.2 Negative-Sequence Current 292
4.6.3 Overcurrent 302
4.6.4 Current Transients 302
4.6.5 Overspeed 303
4.7 Grid-Induced Torsional Vibrations 303
4.7.1 Basic Principles of Shaft Torsional Vibration 303
4.7.2 Spring Model of a Turbo-Generator Shaft Train 305
4.7.3 Determination of Shaft Torque and Shaft Torsional Stress 308
4.7.4 Material Changes Due to Torsional Vibrations 308
4.7.5 Types of Grid-Induced Events 308
4.7.6 Monitoring of Torsional Vibration Events 315
4.7.7 Industry Experience and Alleviation Techniques 315
4.8 Excitation and Voltage Regulation 316
4.8.1 The Exciter 316
4.8.2 Excitation Control 317
4.9 Performance Curves 318
4.9.1 Loss Curves 318
4.9.2 Efficiency Curves 319
4.10 Sample of Generator Operating Instructions 319
References 330
5 MONITORING AND DIAGNOSTICS 331
5.1 Generator Monitoring Philosophies 332
5.2 Monitoring Versus Protection: Definition and Practice 333
5.3 Extent of Monitoring Versus Cost and Benefits 335
5.4 Simple Monitoring With Static High-Level Alarm Limits 335
5.5 Dynamic Monitoring With Load-Varying Alarm Limits 336
5.6 Artificial Intelligence Diagnostic Systems 342
5.7 Monitoring A Single Parameter Versus A Multifunction Instrument 345
5.8 Monitored Parameters 346
5.8.1 Generator Electrical Parameters 347
5.8.2 Stator Core and Frame 352
5.8.3 Stator Winding 364
5.8.4 Rotor 391
5.8.5 Excitation System 409
5.8.6 Hydrogen Cooling System 410
5.8.7 Lube-Oil System 415
5.8.8 Seal-Oil System 418
5.8.9 Stator Cooling Water System 421
References 427
6 GENERATOR PROTECTION 429
6.1 Basic Protection Philosophy 429
6.2 Generator Protective Functions 431
6.2.1 Protection Alarm Response 434
6.2.2 Protection Trip Response 435
6.3 Brief Description of Protective Functions 435
6.3.1 Synchronizer and Sync-Check Relays (Functions 15 and 25) 436
6.3.2 Short-Circuit Protection (Functions 21, 50, 51, 51V, and 87) 436
6.3.3 Volts/Hertz Protection (Function 24) 439
6.3.4 Over- and Undervoltage Protection (Functions 59 and 27) 443
6.3.5 Reverse Power Protection (Function 32) 443
6.3.6 Loss-of-Field Protection (Function 40) 445
6.3.7 Stator Unbalanced Current Protection (Function 46) 445
6.3.8 Stator and Rotor Thermal Protection (Function 49) 447
6.3.9 Voltage Balance Protection (Function 60) 448
6.3.10 Time Overcurrent Protection for Detection of Turn-to-Turn Faults (Function 61) 449
6.3.11 Breaker Failure Protection (Function 62B) 450
6.3.12 Rotor Ground-Fault Protection (Function 64F) 451
6.3.13 Stator Ground Fault Protection (Functions 27, 51, 59) 453
6.3.14 Stator Ground Fault Protection Utilizing Third Harmonic-Based Relays 454
6.3.15 Stator Ground Fault Protection by Low-Frequency Injection 455
6.3.16 Over-/Underfrequency Protection (Function 81) 455
6.3.17 Out-of-Step Operation (Loss of Synchronism, Function 78) 456
6.4 Specialized Protection Schemes 457
6.4.1 Protection against Accidental Energization 457
6.4.2 dc Field Ground Discrimination 459
6.4.3 Vibration Considerations 462
6.4.4 Operation of the Isolated-Phase Bus (IPB) at Reduced Cooling and Risks from H2 Leaks into the IPB 463
6.4.5 Calculation of the H2-Air Mixture in the IPB for a Given H2 Leak from the Generator into the IPB 465
6.4.6 Calculation of Stator and Rotor Amortisseur Motoring Currents 472
6.4.7 Numerical Example for Calculating Rotor Amortisseur Motoring Currents 474
6.4.8 Voltage Across Field Terminals During an Induction Motoring or Generation Event 474
6.5 Tripping and Alarming Methods 475
References 477
II INSPECTION, MAINTENANCE, AND TESTING
7 INSPECTION PRACTICES AND METHODOLOGY 481
7.1 Site Preparation 481
7.1.1 Foreign Material Exclusion 481
7.1.2 Foreign Material Exclusion: Procedures 487
7.2 Experience and Training 490
7.3 Safety Procedures 491
7.3.1 Mechanical Obstacle Avoidance and Electrical Clearances 491
7.3.2 Confined Space Entry 495
7.3.3 Plan for Emergency Extraction 496
7.4 Inspection Frequency 496
7.5 Generator Accessibility 497
7.6 Inspection Tools 499
7.7 Inspection Forms 505
References 520
8 STATOR INSPECTION 521
8.1 Stator Frame and Casing 522
8.1.1 External Components 522
8.1.2 Internal Components 536
8.1.3 Caged Stator Cores-Inspection and Removal 547
8.2 Stator Core 549
8.2.1 Stator Bore Contamination 549
8.2.2 Blocked Cooling Vent Ducts 552
8.2.3 Iron Oxide Deposits 553
8.2.4 Loose Core Iron/Fretting and Interlaminar Failures 555
8.2.5 Bent/Broken Laminations in the Bore 571
8.2.6 Space Block Support and Migration 572
8.2.7 Migration of Broken Core Plate and Space Block Thick Plates 573
8.2.8 Laminations Bulging into Air Vents 574
8.2.9 Greasing/Oxide Deposits on Core Bolts 575
8.2.10 Core-Compression Plates 577
8.2.11 Core-End Flux Screens...
Details
| Erscheinungsjahr: | 2018 |
|---|---|
| Fachbereich: | Kraftwerktechnik |
| Genre: | Technik |
| Rubrik: | Naturwissenschaften & Technik |
| Medium: | Buch |
| Seiten: | 1040 |
| Inhalt: | 1040 S. |
| ISBN-13: | 9781119389767 |
| ISBN-10: | 1119389763 |
| Sprache: | Englisch |
| Einband: | Gebunden |
| Autor: |
Klempner, Geoff
Kerszenbaum, Isidor |
| Auflage: | 3rd edition |
| Hersteller: | Wiley |
| Maße: | 231 x 157 x 43 mm |
| Von/Mit: | Geoff Klempner (u. a.) |
| Erscheinungsdatum: | 07.08.2018 |
| Gewicht: | 1,356 kg |
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