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Power system analysis & design / Glover, J. Duncan
Titre : Power system analysis & design Type de document : texte imprimé Auteurs : Glover, J. Duncan, Auteur ; Overbye, Thomas Jeffrey Sarma, Mulukutla S, Auteur Mention d'édition : sixth edition. Editeur : USA: Cengage brain,2016 Année de publication : 2016 Importance : 941 p. Présentation : ill. Format : 19.05 x 4.06 x 23.37 cm ISBN/ISSN/EAN : 978-1-305-63618-7 Note générale : Electric power systems : Design and construction : Data processing
Electric circuit analysis
Microcomputers
Réseaux électriques (énergie)
Circuits électriques : Analyse
Micro-ordinateursLangues : Anglais (eng) Résumé : Machine generated contents note: Case Study: How the Free Market Rocked the Grid.
1.1.History of Electric Power Systems.
1.2.Present and Future Trends.
1.3.Electric Utility Industry Structure.
1.4.Computers in Power System Engineering.
1.5.PowerWorld Simulator.
Case Study: Key Connections.
2.1.Phasors.
2.2.Instantaneous Power in Single-Phase AC Circuits.
2.3.Complex Power.
2.4.Network Equations.
2.5.Balanced Three-Phase Circuits.
2.6.Power in Balanced Three-Phase Circuits.
2.7.Advantages of Balanced Three-Phase versus Single-Phase Systems.
Case Study: Power Transformers-Life Management and Extension.
3.1.The Ideal Transformer.
3.2.Equivalent Circuits for Practical Transformers.
3.3.The Per-Unit System.
3.4.Three-Phase Transformer Connections and Phase Shift.
3.5.Per-Unit Equivalent Circuits of Balanced Three-Phase Two-Winding Transformers.
3.6.Three-Winding Transformers.
3.7.Autotransformers.
Note continued: 3.8.Transformers with Off-Nominal Turns Ratios.
Case Study: Integrating North America's Power Grid.
Case Study: Grid Congestion.
Unclogging the Arteries of North America's Power Grid.
4.1.Transmission Line Design Considerations.
4.2.Resistance.
4.3.Conductance.
4.4.Inductance: Solid Cylindrical Conductor.
4.5.Inductance: Single-Phase Two-Wire Line and Three-Phase Three-Wire Line with Equal Phase Spacing.
4.6.Inductance: Composite Conductors, Unequal Phase Spacing, Bundled Conductors.
4.7.Series Impedances: Three-Phase Line with Neutral Conductors and Earth Return.
4.8.Electric Field and Voltage: Solid Cylindrical Conductor.
4.9.Capacitance: Single-Phase Two-Wire Line and Three-Phase Three-Wire Line with Equal Phase Spacing.
4.10.Capacitance: Stranded Conductors, Unequal Phase Spacing, Bundled Conductors.
4.11.Shunt Admittances: Lines with Neutral Conductors and Earth Return.
Note continued: 4.12.Electric Field Strength at Conductor Surfaces and at Ground Level.
4.13.Parallel Circuit Three-Phase Lines.
Case Study: The ABCs of HVDC Transmission Technologies: An Overview of High Voltage Direct Current Systems and Applications.
5.1.Medium and Short Line Approximations.
5.2.Transmission-Line Differential Equations.
5.3.Equivalent Circuit.
5.4.Lossless Lines.
5.5.Maximum Power Flow.
5.6.Line Loadability.
5.7.Reactive Compensation Techniques.
Case Study: Finding Flexibility-Cycling the Conventional Fleet.
6.1.Direct Solutions to Linear Algebraic Equations: Gauss Elimination.
6.2.Iterative Solutions to Linear Algebraic Equations: Jacobi and Gauss-Seidel.
6.3.Iterative Solutions to Nonlinear Algebraic Equations: Newton-Raphson.
6.4.The Power Flow Problem.
6.5.Power Flow Solution by Gauss-Seidel.
6.6.Power Flow Solution by Newton-Raphson.
6.7.Control of Power Flow.
6.8.Sparsity Techniques.
Note continued: 6.9.Fast Decoupled Power Flow.
6.10.The "DC" Power Flow.
6.11.Power Flow Modeling of Wind Generation.
6.12.Economic Dispatch.
6.13.Optimal Power Flow.
Design Projects 1-3.
Case Study: Short-Circuit Modeling of a Wind Power Plant.
7.1.Series R-L Circuit Transients.
7.2.Three-Phase Short Circuit-Unloaded Synchronous Machine.
7.3.Power System Three-Phase Short Circuits.
7.4.Bus Impedance Matrix.
7.5.Circuit Breaker and Fuse Selection.
Design Project 3 (continued).
Case Study: Technological Progress in High-Voltage Gas-Insulated Substations.
8.1.Definition of Symmetrical Components.
8.2.Sequence Networks of Impedance Loads.
8.3.Sequence Networks of Series Impedances.
8.4.Sequence Networks of Three-Phase Lines.
8.5.Sequence Networks of Rotating Machines.
8.6.Per-Unit Sequence Models of Three-Phase Two-Winding Transformers.
8.7.Per-Unit Sequence Models of Three-Phase Three-Winding Transformers.
Note continued: 8.8.Power in Sequence Networks.
Case Study: Innovative Medium Voltage Switchgear for Today's Applications.
9.1.System Representation.
9.2.Single Line-to-Ground Fault.
9.3.Line-to-Line Fault.
9.4.Double Line-to-Ground Fault.
9.5.Sequence Bus Impedance Matrices.
Design Project 3 (continued).
Design Project 4.
Case Study: Upgrading Relay Protection Be Prepared for the Next Replacement or Upgrade Project.
10.1.System Protection Components.
10.2.Instrument Transformers.
10.3.Overcurrent Relays.
10.4.Radial System Protection.
10.5.Reclosers and Fuses.
10.6.Directional Relays.
10.7.Protection of a Two-Source System with Directional Relays.
10.8.Zones of Protection.
10.9.Line Protection with Impedance (Distance) Relays.
10.10.Differential Relays.
10.11.Bus Protection with Differential Relays.
10.12.Transformer Protection with Differential Relays.
10.13.Pilot Relaying.
10.14.Numeric Relaying.
Note continued: Case Study: Down, but Not Out.
11.1.The Swing Equation.
11.2.Simplified Synchronous Machine Model and System Equivalents.
11.3.The Equal-Area Criterion.
11.4.Numerical Integration of the Swing Equation.
11.5.Multimachine Stability.
11.6.A Two-Axis Synchronous Machine Model.
11.7.Wind Turbine Machine Models.
11.8.Design Methods for Improving Transient Stability.
Case Study: No Light in August: Power System Restoration Following the 2003 North American Blackout.
12.1.Generator-Voltage Control.
12.2.Turbine-Governor Control.
12.3.Load-Frequency Control.
Case Study: Surge Arresters.
Case Study: Emergency Response.
13.1.Traveling Waves on Single-Phase Lossless Lines.
13.2.Boundary Conditions for Single-Phase Lossless Lines.
13.3.Bewley Lattice Diagram.
13.4.Discrete-Time Models of Single-Phase Lossless Lines and Lumped RLC Elements.
13.5.Lossy Lines.
13.6.Multiconductor Lines.
13.7.Power System Overvoltages.
Note continued: 13.8.Insulation Coordination.
Case Study: It's All in the Plans.
14.1.Introduction to Distribution.
14.2.Primary Distribution.
14.3.Secondary Distribution.
14.4.Transformers in Distribution Systems.
14.5.Shunt Capacitors in Distribution Systems.
14.6.Distribution Software.
14.7.Distribution Reliability.
14.8.Distribution Automation.
14.9.Smart GridsPower system analysis & design [texte imprimé] / Glover, J. Duncan, Auteur ; Overbye, Thomas Jeffrey Sarma, Mulukutla S, Auteur . - sixth edition. . - USA: Cengage brain,2016, 2016 . - 941 p. : ill. ; 19.05 x 4.06 x 23.37 cm.
ISBN : 978-1-305-63618-7
Electric power systems : Design and construction : Data processing
Electric circuit analysis
Microcomputers
Réseaux électriques (énergie)
Circuits électriques : Analyse
Micro-ordinateurs
Langues : Anglais (eng)
Résumé : Machine generated contents note: Case Study: How the Free Market Rocked the Grid.
1.1.History of Electric Power Systems.
1.2.Present and Future Trends.
1.3.Electric Utility Industry Structure.
1.4.Computers in Power System Engineering.
1.5.PowerWorld Simulator.
Case Study: Key Connections.
2.1.Phasors.
2.2.Instantaneous Power in Single-Phase AC Circuits.
2.3.Complex Power.
2.4.Network Equations.
2.5.Balanced Three-Phase Circuits.
2.6.Power in Balanced Three-Phase Circuits.
2.7.Advantages of Balanced Three-Phase versus Single-Phase Systems.
Case Study: Power Transformers-Life Management and Extension.
3.1.The Ideal Transformer.
3.2.Equivalent Circuits for Practical Transformers.
3.3.The Per-Unit System.
3.4.Three-Phase Transformer Connections and Phase Shift.
3.5.Per-Unit Equivalent Circuits of Balanced Three-Phase Two-Winding Transformers.
3.6.Three-Winding Transformers.
3.7.Autotransformers.
Note continued: 3.8.Transformers with Off-Nominal Turns Ratios.
Case Study: Integrating North America's Power Grid.
Case Study: Grid Congestion.
Unclogging the Arteries of North America's Power Grid.
4.1.Transmission Line Design Considerations.
4.2.Resistance.
4.3.Conductance.
4.4.Inductance: Solid Cylindrical Conductor.
4.5.Inductance: Single-Phase Two-Wire Line and Three-Phase Three-Wire Line with Equal Phase Spacing.
4.6.Inductance: Composite Conductors, Unequal Phase Spacing, Bundled Conductors.
4.7.Series Impedances: Three-Phase Line with Neutral Conductors and Earth Return.
4.8.Electric Field and Voltage: Solid Cylindrical Conductor.
4.9.Capacitance: Single-Phase Two-Wire Line and Three-Phase Three-Wire Line with Equal Phase Spacing.
4.10.Capacitance: Stranded Conductors, Unequal Phase Spacing, Bundled Conductors.
4.11.Shunt Admittances: Lines with Neutral Conductors and Earth Return.
Note continued: 4.12.Electric Field Strength at Conductor Surfaces and at Ground Level.
4.13.Parallel Circuit Three-Phase Lines.
Case Study: The ABCs of HVDC Transmission Technologies: An Overview of High Voltage Direct Current Systems and Applications.
5.1.Medium and Short Line Approximations.
5.2.Transmission-Line Differential Equations.
5.3.Equivalent Circuit.
5.4.Lossless Lines.
5.5.Maximum Power Flow.
5.6.Line Loadability.
5.7.Reactive Compensation Techniques.
Case Study: Finding Flexibility-Cycling the Conventional Fleet.
6.1.Direct Solutions to Linear Algebraic Equations: Gauss Elimination.
6.2.Iterative Solutions to Linear Algebraic Equations: Jacobi and Gauss-Seidel.
6.3.Iterative Solutions to Nonlinear Algebraic Equations: Newton-Raphson.
6.4.The Power Flow Problem.
6.5.Power Flow Solution by Gauss-Seidel.
6.6.Power Flow Solution by Newton-Raphson.
6.7.Control of Power Flow.
6.8.Sparsity Techniques.
Note continued: 6.9.Fast Decoupled Power Flow.
6.10.The "DC" Power Flow.
6.11.Power Flow Modeling of Wind Generation.
6.12.Economic Dispatch.
6.13.Optimal Power Flow.
Design Projects 1-3.
Case Study: Short-Circuit Modeling of a Wind Power Plant.
7.1.Series R-L Circuit Transients.
7.2.Three-Phase Short Circuit-Unloaded Synchronous Machine.
7.3.Power System Three-Phase Short Circuits.
7.4.Bus Impedance Matrix.
7.5.Circuit Breaker and Fuse Selection.
Design Project 3 (continued).
Case Study: Technological Progress in High-Voltage Gas-Insulated Substations.
8.1.Definition of Symmetrical Components.
8.2.Sequence Networks of Impedance Loads.
8.3.Sequence Networks of Series Impedances.
8.4.Sequence Networks of Three-Phase Lines.
8.5.Sequence Networks of Rotating Machines.
8.6.Per-Unit Sequence Models of Three-Phase Two-Winding Transformers.
8.7.Per-Unit Sequence Models of Three-Phase Three-Winding Transformers.
Note continued: 8.8.Power in Sequence Networks.
Case Study: Innovative Medium Voltage Switchgear for Today's Applications.
9.1.System Representation.
9.2.Single Line-to-Ground Fault.
9.3.Line-to-Line Fault.
9.4.Double Line-to-Ground Fault.
9.5.Sequence Bus Impedance Matrices.
Design Project 3 (continued).
Design Project 4.
Case Study: Upgrading Relay Protection Be Prepared for the Next Replacement or Upgrade Project.
10.1.System Protection Components.
10.2.Instrument Transformers.
10.3.Overcurrent Relays.
10.4.Radial System Protection.
10.5.Reclosers and Fuses.
10.6.Directional Relays.
10.7.Protection of a Two-Source System with Directional Relays.
10.8.Zones of Protection.
10.9.Line Protection with Impedance (Distance) Relays.
10.10.Differential Relays.
10.11.Bus Protection with Differential Relays.
10.12.Transformer Protection with Differential Relays.
10.13.Pilot Relaying.
10.14.Numeric Relaying.
Note continued: Case Study: Down, but Not Out.
11.1.The Swing Equation.
11.2.Simplified Synchronous Machine Model and System Equivalents.
11.3.The Equal-Area Criterion.
11.4.Numerical Integration of the Swing Equation.
11.5.Multimachine Stability.
11.6.A Two-Axis Synchronous Machine Model.
11.7.Wind Turbine Machine Models.
11.8.Design Methods for Improving Transient Stability.
Case Study: No Light in August: Power System Restoration Following the 2003 North American Blackout.
12.1.Generator-Voltage Control.
12.2.Turbine-Governor Control.
12.3.Load-Frequency Control.
Case Study: Surge Arresters.
Case Study: Emergency Response.
13.1.Traveling Waves on Single-Phase Lossless Lines.
13.2.Boundary Conditions for Single-Phase Lossless Lines.
13.3.Bewley Lattice Diagram.
13.4.Discrete-Time Models of Single-Phase Lossless Lines and Lumped RLC Elements.
13.5.Lossy Lines.
13.6.Multiconductor Lines.
13.7.Power System Overvoltages.
Note continued: 13.8.Insulation Coordination.
Case Study: It's All in the Plans.
14.1.Introduction to Distribution.
14.2.Primary Distribution.
14.3.Secondary Distribution.
14.4.Transformers in Distribution Systems.
14.5.Shunt Capacitors in Distribution Systems.
14.6.Distribution Software.
14.7.Distribution Reliability.
14.8.Distribution Automation.
14.9.Smart GridsRéservation
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