SØG - mellem flere end 8 millioner bøger:

Søg på: Titel, forfatter, forlag - gerne i kombination.
Eller blot på isbn, hvis du kender dette.

Viser: Power System Control and Stability

Power System Control and Stability, 3. udgave
Søgbar e-bog

Power System Control and Stability Vital Source e-bog

Vijay Vittal, James D. McCalley og Paul M. Anderson
(2019)
John Wiley & Sons
1.640,00 kr.
Leveres umiddelbart efter køb
Power System Control and Stability, 3. udgave

Power System Control and Stability

Vijay Vittal, James D. McCalley, Paul M. Anderson og A. A. Fouad
(2019)
Sprog: Engelsk
John Wiley & Sons, Incorporated
1.687,00 kr.
ikke på lager, Bestil nu og få den leveret
om ca. 10 hverdage

Detaljer om varen

  • 3. Udgave
  • Vital Source searchable e-book (Reflowable pages)
  • Udgiver: John Wiley & Sons (Oktober 2019)
  • Forfattere: Vijay Vittal, James D. McCalley og Paul M. Anderson
  • ISBN: 9781119433699

The third edition of the landmark book on power system stability and control, revised and updated with new material 

The revised third edition of Power System Control and Stability continues to offer a comprehensive text on the fundamental principles and concepts of power system stability and control as well as new material on the latest developments in the field. The third edition offers a revised overview of power system stability and a section that explores the industry convention of q axis leading d axis in modeling of synchronous machines.

In addition, the third edition focuses on simulations that utilize digital computers and commercial simulation tools, it offers an introduction to the concepts of the stability analysis of linear systems together with a detailed formulation of the system state matrix. The authors also include a revised chapter that explores both implicit and explicit integration methods for transient stability. Power System Control and Stability offers an in-depth review of essential topics and:

  • Discusses topics of contemporary and future relevance in terms of modeling, analysis and control
  • Maintains the approach, style, and analytical rigor of the two original editions
  • Addresses both power system planning and operational issues in power system control and stability
  • Includes updated information and new chapters on modeling and simulation of round-rotor synchronous machine model, excitation control, renewable energy resources such as wind turbine generators and solar photovoltaics, load modeling, transient voltage instability, modeling and representation of three widely used FACTS devices in the bulk transmission network, and the modeling and representation of appropriate protection functions in transient stability studies
  • Contains a set of challenging problems at the end of each chapter

Written for graduate students in electric power and professional power system engineers, Power System Control and Stability offers an invaluable reference to basic principles and incorporates the most recent techniques and methods into projects.

Licens varighed:
Bookshelf online: 5 år fra købsdato.
Bookshelf appen: ubegrænset dage fra købsdato.

Udgiveren oplyser at følgende begrænsninger er gældende for dette produkt:
Print: 10 sider kan printes ad gangen
Copy: højest 2 sider i alt kan kopieres (copy/paste)

Detaljer om varen

  • 3. Udgave
  • Hardback: 832 sider
  • Udgiver: John Wiley & Sons, Incorporated (Oktober 2019)
  • Forfattere: Vijay Vittal, James D. McCalley, Paul M. Anderson og A. A. Fouad
  • ISBN: 9781119433712

The third edition of the landmark book on power system stability and control, revised and updated with new material 

The revised third edition of Power System Control and Stability continues to offer a comprehensive text on the fundamental principles and concepts of power system stability and control as well as new material on the latest developments in the field. The third edition offers a revised overview of power system stability and a section that explores the industry convention of q axis leading d axis in modeling of synchronous machines.

In addition, the third edition focuses on simulations that utilize digital computers and commercial simulation tools, it offers an introduction to the concepts of the stability analysis of linear systems together with a detailed formulation of the system state matrix. The authors also include a revised chapter that explores both implicit and explicit integration methods for transient stability. Power System Control and Stability offers an in-depth review of essential topics and:

  • Discusses topics of contemporary and future relevance in terms of modeling, analysis and control
  • Maintains the approach, style, and analytical rigor of the two original editions
  • Addresses both power system planning and operational issues in power system control and stability
  • Includes updated information and new chapters on modeling and simulation of round-rotor synchronous machine model, excitation control, renewable energy resources such as wind turbine generators and solar photovoltaics, load modeling, transient voltage instability, modeling and representation of three widely used FACTS devices in the bulk transmission network, and the modeling and representation of appropriate protection functions in transient stability studies
  • Contains a set of challenging problems at the end of each chapter

Written for graduate students in electric power and professional power system engineers, Power System Control and Stability offers an invaluable reference to basic principles and incorporates the most recent techniques and methods into projects.

Foreword xiii Preface xv About the Authors xvii
Part I Introduction
Chapter 1 Power System Stability 3
1.1 Introduction 3
1.2 Requirements of a Reliable Electrical Power Service 4
1.3 Statement of the Problem 5
1.3.1 Definition of Stability 5
1.3.2 Classification of Stability Problems 6
1.3.3 Description of Stability Phenomenon 6
1.4 Effect of Impact on System Components 7
1.4.1 Loss of Synchronism 8
1.4.2 Synchronous Machine During a Transient 8
1.5 Methods of Simulation 10
1.5.1 Linearized System Equations 10
1.5.2 Large System with Nonlinear Equations 11
1.6 Planning and Operating Standards 11
Chapter 2 The Elementary Mathematical Model 19
2.1 Swing Equation 19
2.2 Units 21
2.3 Mechanical Torque 22
2.3.1 Unregulated Machines 22
2.3.2 Regulated Machines 24
2.4 Electrical Torque 26
2.4.1 Synchronous Torque 26
2.4.2 Other Electrical Torques 27
2.5 Power-Angle Curve of a Synchronous Machine 27
2.5.1 Classical Representation of a Synchronous Machine in Stability Studies 28
2.5.2 Synchronizing Power Coefficients 29
2.6 Natural Frequencies of Oscillation of a Synchronous Machine 30
2.7 System of One Machine Against an Infinite Bus: The Classical Model 31
2.8 Equal Area Criterion 37
2.8.1 Critical Clearing Angle 38
2.8.2 Application to a One-Machine System 39
2.8.3 Equal Area Criterion for a Two-Machine System 39
2.9 Classical Model of a Multimachine System 40
2.10 Classical Stability Study of a Nine-Bus System 42
2.10.1 Data Preparation 43
2.10.2 Preliminary Calculations 45
2.11 Shortcomings of the Classical Model 51
2.12 Block Diagram of One Machine 53
Chapter 3 System Response to Small Disturbances 61
3.1 Introduction 61
3.2 Types of Problems Studied 62
3.2.1 System Response to Small Impacts 62
3.2.2 Distribution of Power Impacts 62
3.3 The Unregulated Synchronous Machine 63
3.3.1 Demagnetizing Effect of Armature Reaction 64
3.3.2 Effect of Small Changes of Speed 65
3.4 Modes of Oscillation of an Unregulated Multimachine System 66
3.5 Regulated Synchronous Machine 73
3.5.1 Voltage Regulator with One Time Lag 73
3.5.2 Governor with One Time Lag 75
3.6 Distribution of Power Impacts 76
3.6.1 Linearization 77
3.6.2 A Special Case: t = 0+ 78
3.6.3 Average Behavior Prior to Governor Action ( t = t 1) 79
Part II Electrical and Electromagnetic Dynamic Performance
Chapter 4 The Synchronous Machine 91
4.1 Introduction 91
4.2 Park''s Transformation 91
4.3 Flux Linkage Equations 94
4.3.1 Stator Self-Inductances 94
4.3.2 Rotor Self-Inductances 95
4.3.3 Stator Mutual Inductances 95
4.3.4 Rotor Mutual Inductances 95
4.3.5 Stator-to-Rotor Mutual Inductances 95
4.3.6 Transformation of Inductances 96
4.4 Voltage Equations 97
4.5 Formulation of State-Space Equations 99
4.6 Current Formulation 100
4.7 Per-Unit Conversion 101
4.7.1 Choosing a Base for Stator Quantities 102
4.7.2 Choosing a Base for Rotor Quantities 103
4.7.3 Comparison with Other Per-Unit Systems 104
4.7.4 The Correspondence of Per-Unit Stator EMF to Rotor Quantities 107
4.8 Normalizing the Voltage Equations 108
4.9 Normalizing the Torque Equations 113
4.9.1 The Normalized Swing Equation 114
4.9.2 Forms of the Swing Equation 114
4.10 Torque and Power 115
4.11 Equivalent Circuit of a Synchronous Machine 117
4.12 The Flux Linkage State-Space Model 119
4.12.1 The Voltage Equations 120
4.12.2 The Torque Equation 120
4.12.3 Machine Equations with Saturation Neglected 121
4.12.4 Treatment of Saturation 123
4.13 Load Equations 124
4.13.1 Synchronous Machine Connected to an Infinite Bus 124
4.13.2 Current Model 126
4.13.3 The Flux Linkage Model 127
4.14 Subtransient and Transient Inductances and Time Constants 131
4.14.1 Time Constants 133
4.15 Simplified Models of the Synchronous Machine 136
4.15.1 Neglecting Damper Windings: The E''q (One-Axis) Model 137
4.15.2 Voltage Behind Subtransient Reactance: The E" Model 142
4.15.3 Neglecting λd and λq for a Cylindrical Rotor Machine: The Two-Axis Model 150
4.15.4 Neglecting Amortisseur Effects and λd and λq Terms: The One-Axis Model 153
4.15.5 Assuming Constant Flux Linkage in the Main Field Winding 154
4.16 Parameter Determination for Generator Dynamic Models 155
Chapter 5 The Simulation of Synchronous Machines 165
5.1 Introduction 165
5.2 Steady-State Equations and Phasor Diagrams 165
5.3 Machine Connected to an Infinite Bus Through a Transmission Line 168
5.4 Machine Connected to an Infinite Bus with Local Load at Machine Terminal 169
5.4.1 Special Case: The Resistive Load, ZL = RL + j0 170
5.4.2 General Case: ZL Arbitrary 171
5.5 Determining Steady-State Conditions 172
5.5.1 Machine Connected to an Infinite Bus with Local Load 173
5.6 Examples 174
5.7 Initial Conditions for a Multimachine System 182
5.8 Determination of Machine Parameters from Manufacturers'' Data 183
5.9 Digital Simulation of Synchronous Machines 188
5.9.1 Digital Computation of Saturation 189
5.9.2 Updating λAD 192
Chapter 6 Load Modeling 199
6.1 Introduction 199
6.2 Static Load Models 200
6.3 Induction Motor Loads 203
6.3.1 Model Development of a Three-Phase Induction Machine 203
6.3.2 Representing Induction Machines in Stability Simulations 213
6.3.3 Stalled Motor Operation 215
6.4 Single-Phase Motors 216
6.4.1 Scroll Compressors 218
6.4.2 Point-on-Wave Effects 219
6.4.3 Dynamic Phasors 219
6.5 Power Electronic Loads 221
6.6 Self-Restoring Loads 224
6.7 Distributed Energy Resources 225
6.8 Composite Load Models 227
6.9 Data Development 229
6.9.1 Component Based 230
6.9.2 Measurement Based 232
Chapter 7 Simulation of Multimachine Systems 239
7.1 Introduction 239
7.2 Statement of the Problem 239
7.3 Matrix Representation of a Passive Network 240
7.3.1 Network in the Transient State 242
7.3.2 Converting to a Common Reference Frame 243
7.4 Converting Machine Coordinates to System Reference 244
7.5 Relation Between Machine Currents and Voltages 245
7.6 System Order 249
7.7 Machines Represented by Classical Methods 249
7.8 Linearized Model for the Network 252
7.9 Hybrid Formulation 258
7.10 Network Equations with Flux Linkage Model 260
7.11 Total System Equations 262
7.12 Alternating Solution Method 264
7.12.1 Nonlinear Loads 265
7.12.2 Network-Machine Interface 268
7.13 Simultaneous Solution Method 275
7.14 Design of Numerical Solvers 277
Chapter 8 Small-Signal Stability Analysis 281
8.1 Introduction 281
8.2 Fundamentals of Linear System Stability 282
8.3 Linearization of the Generator State-Space Current Model 284
8.4 Linearization of the Load Equation for the One-Machine Problem 288
8.5 Linearization of the Flux Linkage Model 293
8.6 State Matrix for Multimachine Systems 298
8.6.1 Formulation of the State Matrix 298
8.6.2 Representation of Static Loads in the State Matrix 300
8.7 Simplified Linear Model 312
8.7.1 The E'' Equation 312
8.7.2 Electrical Torque Equation 313
8.7.3 Terminal Voltage Equation 314
8.7.4 Summary of Equations 315
8.7.5 Effect of Loading 318
8.7.6 Comparison with Classical Model 320
8.8 Block Diagrams 321
8.9 State-Space Representation of Simplified Model 322
Chapter 9 Excitation Systems 325
9.1 Simplified View of Excitation Control 325
9.2 Control Configurations 327
9.3 Typical Excitation Configurations 328
9.3.1 Primitive Systems 328
9.3.2 Type DC Excitation Control Systems with DC Generator-Commutator Exciters 332
9.3.3 Type AC Excitation Control Systems with Alternator-Rectifier Exciters 332
9.3.4 Type AC Excitation Control Systems with Alternator-SCR Exciter Systems 334
9.3.5 Type ST Excitation Control Systems with Compound-Rectifier Exciter Systems 335
9.3.6 Type ST Excitation Control System with Compound-Rectifier Exciter Plus Potential-Source-Rectifier Exciter 336
9.3.7 Type ST Excitation Control Systems with Potential-Source-Rectifier Exciter 336
9.4 Excitation Control System Definitions 337
9.4.1 Voltage Response Ratio 339
9.4.2 Exciter Voltage Ratings 341
9.4.3 Other Specifications 342
9.5 Voltage Regulator 344
9.5.1 Electromechanical Regulators 344
9.5.2 Early Electronic Regulators 345
9.5.3 Rotating Amplifier Regulators 345
9.5.4 Magnetic Amplifier Regulators 346
9.5.5 Digital Excitation Systems 348
9.6 Exciter Buildup 348
9.6.1 The DC Generator Exciter 348
9.6.2 Linear Approximations for DC Generator Exciters 356
9.6.3 The AC Generator Exciters 358
9.6.4 Solid-State Exciters 359
9.6.5 Buildup of a Loaded DC Exciter 360
9.6.6 Normalization of Exciter Equations 360
9.7
De oplyste priser er inkl. moms

Polyteknisk Boghandel

har gennem mere end 50 år været studieboghandlen på DTU og en af Danmarks førende specialister i faglitteratur.

 

Vi lagerfører et bredt udvalg af bøger, ikke bare inden for videnskab og teknik, men også f.eks. ledelse, IT og meget andet.

Læs mere her


Trykt eller digital bog?

Ud over trykte bøger tilbyder vi tre forskellige typer af digitale bøger:

 

Vital Source Bookshelf: En velfungerende ebogsplatform, hvor bogen downloades til din computer og/eller mobile enhed.

 

Du skal bruge den gratis Bookshelf software til at læse læse bøgerne - der er indbygget gode værktøjer til f.eks. søgning, overstregning, notetagning mv. I langt de fleste tilfælde vil du samtidig have en sideløbende 1825 dages online adgang. Læs mere om Vital Source bøger

 

Levering: I forbindelse med købet opretter du et login. Når du har installeret Bookshelf softwaren, logger du blot ind og din bog downloades automatisk.

 

 

Adobe ebog: Dette er Adobe DRM ebøger som downloades til din lokale computer eller mobil enhed.

 

For at læse bøgerne kræves særlig software, som understøtter denne type. Softwaren er gratis, men du bør sikre at du har rettigheder til installere software på den maskine du påtænker at anvende den på. Læs mere om Adobe DRM bøger

 

Levering: Et download link sendes pr email umiddelbart efter købet.

 


Ibog: Dette er en online bog som kan læses på udgiverens website. 

Der kræves ikke særlig software, bogen læses i en almindelig browser.

 

Levering: Vores medarbejder sender dig en adgangsnøgle pr email.

 

Vi gør opmærksom på at der ikke er retur/fortrydelsesret på digitale varer.