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Auteur P.M. Anderson
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Affiner la recherche Interroger des sources externesPower system control and stability / P.M. Anderson
Titre : Power system control and stability Type de document : texte imprimé Auteurs : P.M. Anderson, Auteur ; A.A. Fouad, Auteur Mention d'édition : 2 ème ed. Editeur : Boca Raton; London; New York : CRC Press Année de publication : 2003 Collection : Electric Power Engineering Series Importance : 658 p. Présentation : couv. ill. en coul., ill. Format : 26 cm. ISBN/ISSN/EAN : 978-0-471-23862-1 Langues : Anglais (eng) Catégories : ELECTROTECHNIQUE Index. décimale : 10-03 Machines éléctriques Résumé : Leading-edge coverage of modeling of the power system stability problem
Providing a comprehensive description of the dynamic condition of the power system, this new edition of an industry-standard text presents critical information on synchronous generators and their excitation systems, as well as extensive material on mathematical modeling of these critical components. It offers up-to-date treatment of the modeling of the power system stability problem–from the generator to the transmission system to the electrical loads.
Fully updated and expanded to include the latest developments in the field, Power System Control and Stability, Second Edition describes the mechanical system that drives the electric generators, and the dynamic reaction between the prime mover and generator systems. It explains how to:
Analyze the dynamic performance of interconnected power systems
Examine the characteristics of the various components of a power system during normal operating conditions and during disturbances
Explore detailed mathematical models of system components and analyze system behavior using the necessary computational tools
Written for practicing engineers in the electric power industry as well as advanced students interested in power system dynamic behavior, this must-have guide will help you understand the dynamic performance of power systems.Note de contenu : Contents:
Pt. I Introduction
Ch. 1 Power System Stability
Ch. 2 The Elementary Mathematical Model
Ch. 3 System Response to Small Disturbances
Pt. II The Electromagnetic Torque
Ch. 4 The Synchronous Machine
Ch. 5 The Simulation of Synchronous Machines
Ch. 6 Linear Models of the Synchronous Machine
Ch. 7 Excitation Systems
Ch. 8 Effect of Excitation on Stability
Ch. 9 Multimachine Systems with Constant Impedance Loads
Pt. III The Mechanical Torque Power System Control and Stability
Ch. 10 Speed Governing
Ch. 11 Steam Turbine Prime Movers
Ch. 12 Hydraulic Turbine Prime Movers
Ch. 13 Combustion Turbine and Combined-Cycle Power Plants
App. A Trigonometric Identities for Three-Phase Systems
App. B Some Computer Methods for Solving Differential Equations
App. C: Normalization
App. D: Typical System Data
App. E Excitation Control System Definitions
App. F Control System Components
App. G Pressure Control Systems
App. H The Governor Equations
App. I Wave Equations for a Hydraulic Conduit
App. J Hydraulic Servomotors
Power system control and stability [texte imprimé] / P.M. Anderson, Auteur ; A.A. Fouad, Auteur . - 2 ème ed. . - Boca Raton; London; New York : CRC Press, 2003 . - 658 p. : couv. ill. en coul., ill. ; 26 cm.. - (Electric Power Engineering Series) .
ISBN : 978-0-471-23862-1
Langues : Anglais (eng)
Catégories : ELECTROTECHNIQUE Index. décimale : 10-03 Machines éléctriques Résumé : Leading-edge coverage of modeling of the power system stability problem
Providing a comprehensive description of the dynamic condition of the power system, this new edition of an industry-standard text presents critical information on synchronous generators and their excitation systems, as well as extensive material on mathematical modeling of these critical components. It offers up-to-date treatment of the modeling of the power system stability problem–from the generator to the transmission system to the electrical loads.
Fully updated and expanded to include the latest developments in the field, Power System Control and Stability, Second Edition describes the mechanical system that drives the electric generators, and the dynamic reaction between the prime mover and generator systems. It explains how to:
Analyze the dynamic performance of interconnected power systems
Examine the characteristics of the various components of a power system during normal operating conditions and during disturbances
Explore detailed mathematical models of system components and analyze system behavior using the necessary computational tools
Written for practicing engineers in the electric power industry as well as advanced students interested in power system dynamic behavior, this must-have guide will help you understand the dynamic performance of power systems.Note de contenu : Contents:
Pt. I Introduction
Ch. 1 Power System Stability
Ch. 2 The Elementary Mathematical Model
Ch. 3 System Response to Small Disturbances
Pt. II The Electromagnetic Torque
Ch. 4 The Synchronous Machine
Ch. 5 The Simulation of Synchronous Machines
Ch. 6 Linear Models of the Synchronous Machine
Ch. 7 Excitation Systems
Ch. 8 Effect of Excitation on Stability
Ch. 9 Multimachine Systems with Constant Impedance Loads
Pt. III The Mechanical Torque Power System Control and Stability
Ch. 10 Speed Governing
Ch. 11 Steam Turbine Prime Movers
Ch. 12 Hydraulic Turbine Prime Movers
Ch. 13 Combustion Turbine and Combined-Cycle Power Plants
App. A Trigonometric Identities for Three-Phase Systems
App. B Some Computer Methods for Solving Differential Equations
App. C: Normalization
App. D: Typical System Data
App. E Excitation Control System Definitions
App. F Control System Components
App. G Pressure Control Systems
App. H The Governor Equations
App. I Wave Equations for a Hydraulic Conduit
App. J Hydraulic Servomotors
Exemplaires
Code-barres Cote Support Localisation Section Disponibilité N.Inventaire 991 10-03-27 Livre Bibliothèque de Génie Electrique- USTO Documentaires Exclu du prêt 991 992 10-03-27 Livre Bibliothèque de Génie Electrique- USTO Documentaires Exclu du prêt 992 993 10-03-27 Livre Bibliothèque de Génie Electrique- USTO Documentaires Exclu du prêt 993
Titre : Subsynchronous resonance in power systems Type de document : texte imprimé Auteurs : P.M. Anderson, Auteur ; Basant L. Agrawal, Auteur ; J. E. Van Ness, Auteur Editeur : New York : The Institution of Electrical and Electronics Engineers,inc. Année de publication : 1990 Collection : IEEE press Importance : 268 p. Présentation : couv. ill. en coul., ill. Format : 24 cm. ISBN/ISSN/EAN : 978-0-7803-5350-3 Langues : Anglais (eng) Catégories : ELECTROTECHNIQUE Index. décimale : 10-05 Electronique de puissance et industrielle Résumé : Subsynchronous Resonance in Power Systems provides in-depth guidance toward the parameters, modeling, and analysis of this complex subclass of power systems. Emphasizing field testing to determine the data required, this book facilitates thorough and efficient oscillation and damping modeling using eigenvalues of a system's linear model. Expert discussion provides step-by-step instruction for generator, network, and turbine-generator shaft models, followed by detailed tutorials for model testing and analysis based on IEEE, CORPALS, and SSR eigenvalue analysis. Comprehensive in scope and practical in focus, this book is an invaluable resource for anyone working with frequencies below 60 Hz. Note de contenu : Table of contents:
PART 1: INTRODUCTION.
Chapter 1: Introduction.
PART 2: SYSTEM MODELING.
Chapter 2: The Generator Model.
2.1 The Synchronous Machine Structure.
2.2 The Machine Circuit Inductances.
2.3 Park's Transformation.
2.4 The Voltage Equations.
2.5 The Power and Torque Equations.
2.6 Normalization of the Equations.
2.7 Analysis of the Direct Axis Equations.
2.8 Analysis of the Quadrature Axis Equations.
2.9 Summary of Machine Equations.
2.10 Machine-Network Interface Equations.
2.11 Linear State-Space Machine Equations.
2.12 Excitation Systems.
2.13 Synchronous Machine Saturation.
Chapter 3: The Network Model.
3.1 An Introductory Example.
3.2 The Degenerate Network.
3.3 The Order of Complexity of the Network.
3.4 Finding the Network State Equations.
3.5 Transforming the State Equations.
3.6 Generator Frequency Transformation.
3.7 Modulation of the 60 Hz Network Response.
Chapter 4: The Turbine-Generator Shaft Model.
4.1 Definitions and Conventions.
4.2 The Shaft Torque Equations.
4.3 The Shaft Power Equations.
4.4 Normalization of the Shaft Equations.
4.5 The Incremental Shaft Equations.
4.6 The Turbine Model.
4.7 The Complete Turbine and Shaft Model.
PART 3: SYSTEM PARAMETERS.
Chapter 5: Synchronous Generator Model Parameters.
5.1 Conventional Stability Data.
5.1.1 Approximations Involved in Parameter Computation.
5.2 Measured Data from Field Tests.
5.3 Parameter Fitting from Test Results.
5.4 Sample Test Results.
5.5 Frequency Dependent R and X Data.
5.6 Other Sources of Data.
Chapter 6: Turbine-Generator Shaft Model Parameters.
6.1 The Shaft Spring-Mass Model.
6.2 The Modal Model.
6.3 Field Tests for Frequencies and Damping.
6.4 Damping Tests.
PART 4: SYSTEM ANALYSIS.
Chapter 7: Eigen Analysis.
7.1 State-Space Form of System Equations.
7.2 Solution of the State Equations.
7.3 Finding Eigenvalues and Eigenvectors.
Chapter 8: SSR Eigenvalue Analysis.
8.1 The IEEE First Benchmark Model.
8.2 The IEEE Second Benchmark Model.
8.3 The CORPALS Benchmark Model.
8.4 An Example of SSR Eigenvalue Analysis.
Index.Subsynchronous resonance in power systems [texte imprimé] / P.M. Anderson, Auteur ; Basant L. Agrawal, Auteur ; J. E. Van Ness, Auteur . - New York : The Institution of Electrical and Electronics Engineers,inc., 1990 . - 268 p. : couv. ill. en coul., ill. ; 24 cm.. - (IEEE press) .
ISBN : 978-0-7803-5350-3
Langues : Anglais (eng)
Catégories : ELECTROTECHNIQUE Index. décimale : 10-05 Electronique de puissance et industrielle Résumé : Subsynchronous Resonance in Power Systems provides in-depth guidance toward the parameters, modeling, and analysis of this complex subclass of power systems. Emphasizing field testing to determine the data required, this book facilitates thorough and efficient oscillation and damping modeling using eigenvalues of a system's linear model. Expert discussion provides step-by-step instruction for generator, network, and turbine-generator shaft models, followed by detailed tutorials for model testing and analysis based on IEEE, CORPALS, and SSR eigenvalue analysis. Comprehensive in scope and practical in focus, this book is an invaluable resource for anyone working with frequencies below 60 Hz. Note de contenu : Table of contents:
PART 1: INTRODUCTION.
Chapter 1: Introduction.
PART 2: SYSTEM MODELING.
Chapter 2: The Generator Model.
2.1 The Synchronous Machine Structure.
2.2 The Machine Circuit Inductances.
2.3 Park's Transformation.
2.4 The Voltage Equations.
2.5 The Power and Torque Equations.
2.6 Normalization of the Equations.
2.7 Analysis of the Direct Axis Equations.
2.8 Analysis of the Quadrature Axis Equations.
2.9 Summary of Machine Equations.
2.10 Machine-Network Interface Equations.
2.11 Linear State-Space Machine Equations.
2.12 Excitation Systems.
2.13 Synchronous Machine Saturation.
Chapter 3: The Network Model.
3.1 An Introductory Example.
3.2 The Degenerate Network.
3.3 The Order of Complexity of the Network.
3.4 Finding the Network State Equations.
3.5 Transforming the State Equations.
3.6 Generator Frequency Transformation.
3.7 Modulation of the 60 Hz Network Response.
Chapter 4: The Turbine-Generator Shaft Model.
4.1 Definitions and Conventions.
4.2 The Shaft Torque Equations.
4.3 The Shaft Power Equations.
4.4 Normalization of the Shaft Equations.
4.5 The Incremental Shaft Equations.
4.6 The Turbine Model.
4.7 The Complete Turbine and Shaft Model.
PART 3: SYSTEM PARAMETERS.
Chapter 5: Synchronous Generator Model Parameters.
5.1 Conventional Stability Data.
5.1.1 Approximations Involved in Parameter Computation.
5.2 Measured Data from Field Tests.
5.3 Parameter Fitting from Test Results.
5.4 Sample Test Results.
5.5 Frequency Dependent R and X Data.
5.6 Other Sources of Data.
Chapter 6: Turbine-Generator Shaft Model Parameters.
6.1 The Shaft Spring-Mass Model.
6.2 The Modal Model.
6.3 Field Tests for Frequencies and Damping.
6.4 Damping Tests.
PART 4: SYSTEM ANALYSIS.
Chapter 7: Eigen Analysis.
7.1 State-Space Form of System Equations.
7.2 Solution of the State Equations.
7.3 Finding Eigenvalues and Eigenvectors.
Chapter 8: SSR Eigenvalue Analysis.
8.1 The IEEE First Benchmark Model.
8.2 The IEEE Second Benchmark Model.
8.3 The CORPALS Benchmark Model.
8.4 An Example of SSR Eigenvalue Analysis.
Index.Exemplaires
Code-barres Cote Support Localisation Section Disponibilité N.Inventaire 1686 10-05-49 Livre Bibliothèque de Génie Electrique- USTO Documentaires Exclu du prêt 1686
