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1110-2019 : IEEE Guide for Synchronous Generator Modeling Practices and Parameter Verification with Applications in Power System Stability Analyses / / Institute of Electrical and Electronics Engineers
| 1110-2019 : IEEE Guide for Synchronous Generator Modeling Practices and Parameter Verification with Applications in Power System Stability Analyses / / Institute of Electrical and Electronics Engineers |
| Pubbl/distr/stampa | New York, NY : , : IEEE, , 2020 |
| Descrizione fisica | 1 online resource |
| Disciplina | 621.319 |
| Soggetto topico | Electric power system stability - Mathematical models |
| ISBN | 1-5044-6290-4 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNINA-9910389550103321 |
| New York, NY : , : IEEE, , 2020 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
1110-2019 : IEEE Guide for Synchronous Generator Modeling Practices and Parameter Verification with Applications in Power System Stability Analyses / / Institute of Electrical and Electronics Engineers
| 1110-2019 : IEEE Guide for Synchronous Generator Modeling Practices and Parameter Verification with Applications in Power System Stability Analyses / / Institute of Electrical and Electronics Engineers |
| Pubbl/distr/stampa | New York, NY : , : IEEE, , 2020 |
| Descrizione fisica | 1 online resource |
| Disciplina | 621.319 |
| Soggetto topico | Electric power system stability - Mathematical models |
| ISBN | 1-5044-6290-4 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNISA-996574790303316 |
| New York, NY : , : IEEE, , 2020 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. di Salerno | ||
| ||
Handbook of electrical power system dynamics : modeling, stability, and control / / edited by Mircea Eremia, Mohammad Shahidehpour
| Handbook of electrical power system dynamics : modeling, stability, and control / / edited by Mircea Eremia, Mohammad Shahidehpour |
| Pubbl/distr/stampa | Hoboken, New Jersey : , : John Wiley & Sons Inc., , [2013] |
| Descrizione fisica | 1 online resource (975 p.) |
| Disciplina |
621.3
621.31 |
| Altri autori (Persone) |
ShahidehpourM. <1955->
EremiaMircea |
| Collana | IEEE press series on power engineering |
| Soggetto topico |
Electric power system stability - Mathematical models
Electric power systems - Control Electric machinery - Dynamics |
| ISBN |
1-299-24203-0
1-118-51604-4 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Foreword xxiii -- Acknowledgments xxv -- Contributors xxvii -- 1. INTRODUCTION 1 -- Mircea Eremia and Mohammad Shahidehpour -- PART I POWER SYSTEM MODELING AND CONTROL 7 -- 2. SYNCHRONOUS GENERATOR AND INDUCTION MOTOR 9 -- Mircea Eremia and Constantin Bulac -- 2.1. Theory and Modeling of Synchronous Generator 9 -- 2.2. Theory and Modeling of the Induction Motor 114 -- 3. MODELING THE MAIN COMPONENTS OF THE CLASSICAL POWER PLANTS 137 -- Mohammad Shahidehpour, Mircea Eremia, and Lucian Toma -- 3.1. Introduction 137 -- 3.2. Types of Turbines 138 -- 3.3. Thermal Power Plants 143 -- 3.4. Combined-Cycle Power Plants 158 -- 3.5. Nuclear Power Plants 167 -- 3.6. Hydraulic Power Plants 169 -- 4. WIND POWER GENERATION 179 -- Mohammad Shahidehpour and Mircea Eremia -- 4.1. Introduction 179 -- 4.2. Some Characteristics of Wind Power Generation 181 -- 4.3. State of the Art Technologies 184 -- 4.4. Modeling the Wind Turbine Generators 200 -- 4.5. Fault Ride-Through Capability 223 -- 5. SHORT-CIRCUIT CURRENTS CALCULATION 229 -- Nouredine Hadjsaid, Ion TriSstiu, and Lucian Toma -- 5.1. Introduction 229 -- 5.2. Characteristics of Short-Circuit Currents 232 -- 5.3. Methods of Short-Circuit Currents Calculation 236 -- 5.4. Calculation of Short-Circuit Current Components 264 -- 6. ACTIVE POWER AND FREQUENCY CONTROL 291 -- Les Pereira -- 6.1. Introduction 291 -- 6.2. Frequency Deviations in Practice 293 -- 6.3. Typical Standards and Policies for "Active Power and Frequency Control" or "Load Frequency Control" 294 -- 6.4. System Modeling, Inertia, Droop, Regulation, and Dynamic Frequency Response 297 -- 6.5. Governor Modeling 302 -- 6.6. AGC Principles and Modeling 328 -- 6.7. Other Topics of Interest Related to Load Frequency Control 336 -- 7. VOLTAGE AND REACTIVE POWER CONTROL 340 -- Sandro Corsi and Mircea Eremia -- 7.1. Relationship Between Active and Reactive Powers and Voltage 342 -- 7.2. Equipments for Voltage and Reactive Power Control 347 -- 7.3. Grid Voltage and Reactive Power Control Methods 374.
7.4. Grid Hierarchical Voltage Regulation 399 -- 7.5. Implementation Study of the Secondary Voltage Regulation in Romania 423 -- 7.6. Examples of Hierarchical Voltage Control in the World 429 -- PART II POWER SYSTEM STABILITY AND PROTECTION 451 -- 8. BACKGROUND OF POWER SYSTEM STABILITY 453 -- S.S. (Mani) Venkata, Mircea Eremia, and Lucian Toma -- 8.1. Introduction 453 -- 8.2. Classification of Power Systems Stability 453 -- 8.3. Parallelism Between Voltage Stability and Angular Stability 469 -- 8.4. Importance of Security for Power System Stability 469 -- 9. SMALL-DISTURBANCE ANGLE STABILITY AND ELECTROMECHANICAL OSCILLATION DAMPING 477 -- Roberto Marconato and Alberto Berizzi -- 9.1. Introduction 477 -- 9.2. The Dynamic Matrix 478 -- 9.3. A General Simplified Approach 482 -- 9.4. Major Factors Affecting the Damping of Electromechanical Oscillations 501 -- 9.5. Damping Improvement 546 -- 9.6. Typical Cases of Interarea Or Low-Frequency Electromechanical Oscillations 564 -- 10. TRANSIENT STABILITY 570 -- Nikolai Voropai and Constantin Bulac -- 10.1. General Aspects 570 -- 10.2. Direct Methods for Transient Stability Assessment 572 -- 10.3. Integration Methods for Transient Stability Assessment 603 -- 10.4. Dynamic Equivalents 614 -- 10.5. Transient Stability Assessment of Large Electric Power Systems 638 -- 10.6. Application 645 -- 11. VOLTAGE STABILITY 657 -- Mircea Eremia and Constantin Bulac -- 11.1. Introduction 657 -- 11.2. System Characteristics and Load Modeling 658 -- 11.3. Static Aspects of Voltage Stability 667 -- 11.4. Voltage Instability Mechanisms: Interaction Between Electrical Network, Loads, and Control Devices 674 -- 11.5. Voltage Stability Assessment Methods 688 -- 11.6. Voltage Instability Countermeasures 716 -- 11.7. Application 724 -- 12. POWER SYSTEM PROTECTION 737 -- Klaus-Peter Brand and Ivan De Mesmaeker -- 12.1. Introduction 737 -- 12.2. Summary of IEC 61850 744 -- 12.3. The Protection Chain in Details 746 -- 12.4. Transmission and Distribution Power System Structures 753. 12.5. Properties of the Three-Phase Systems Relevant for Protection 755 -- 12.6. Protection Functions Sorted According to the Objects Protected 759 -- 12.7. From Single Protection Functions to System Protection 773 -- 12.8. Conclusions 780 -- PART III GRID BLACKOUTS AND RESTORATION PROCESS 787 -- 13. MAJOR GRID BLACKOUTS: ANALYSIS, CLASSIFICATION, AND PREVENTION 789 -- Yvon Besanger, Mircea Eremia, and Nikolai Voropai -- 13.1. Introduction 789 -- 13.2. Description of Some Previous Blackouts 792 -- 13.3. Analysis of Blackouts 835 -- 13.4. Economical and Social Effects 847 -- 13.5. Recommendations for Preventing Blackouts 849 -- 13.6. On Some Defense and Restoration Actions 850 -- 13.7. Survivability/vulnerability of Electric Power Systems 856 -- 13.8. Conclusions 860 -- 14. RESTORATION PROCESSES AFTER BLACKOUTS 864 -- Alberto Borghetti, Carlo Alberto Nucci, and Mario Paolone -- 14.1. Introduction 864 -- 14.2. Overview of The Restoration Process 865 -- 14.3. Black-Start-Up Capabilities of Thermal Power Plant: Modeling and Computer Simulations 869 -- 14.4. Description of Computer Simulators 888 -- 14.5. Concluding Remarks 896 -- 15. COMPUTER SIMULATION OF SCALE-BRIDGING TRANSIENTS IN POWER SYSTEMS 900 -- Kai Strunz and Feng Gao -- 15.1. Bridging of Instantaneous and Phasor Signals 901 -- 15.2. Network Modeling 903 -- 15.3. Modeling of Power System Components 909 -- 15.4. Application: Simulation of Blackout 923 -- References 926 -- Index 929. |
| Record Nr. | UNINA-9910141599903321 |
| Hoboken, New Jersey : , : John Wiley & Sons Inc., , [2013] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Handbook of electrical power system dynamics : modeling, stability, and control / / edited by Mircea Eremia, Mohammad Shahidehpour
| Handbook of electrical power system dynamics : modeling, stability, and control / / edited by Mircea Eremia, Mohammad Shahidehpour |
| Pubbl/distr/stampa | Hoboken, New Jersey : , : John Wiley & Sons Inc., , [2013] |
| Descrizione fisica | 1 online resource (975 p.) |
| Disciplina |
621.3
621.31 |
| Altri autori (Persone) |
ShahidehpourM. <1955->
EremiaMircea |
| Collana | IEEE press series on power engineering |
| Soggetto topico |
Electric power system stability - Mathematical models
Electric power systems - Control Electric machinery - Dynamics |
| ISBN |
1-299-24203-0
1-118-51604-4 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Foreword xxiii -- Acknowledgments xxv -- Contributors xxvii -- 1. INTRODUCTION 1 -- Mircea Eremia and Mohammad Shahidehpour -- PART I POWER SYSTEM MODELING AND CONTROL 7 -- 2. SYNCHRONOUS GENERATOR AND INDUCTION MOTOR 9 -- Mircea Eremia and Constantin Bulac -- 2.1. Theory and Modeling of Synchronous Generator 9 -- 2.2. Theory and Modeling of the Induction Motor 114 -- 3. MODELING THE MAIN COMPONENTS OF THE CLASSICAL POWER PLANTS 137 -- Mohammad Shahidehpour, Mircea Eremia, and Lucian Toma -- 3.1. Introduction 137 -- 3.2. Types of Turbines 138 -- 3.3. Thermal Power Plants 143 -- 3.4. Combined-Cycle Power Plants 158 -- 3.5. Nuclear Power Plants 167 -- 3.6. Hydraulic Power Plants 169 -- 4. WIND POWER GENERATION 179 -- Mohammad Shahidehpour and Mircea Eremia -- 4.1. Introduction 179 -- 4.2. Some Characteristics of Wind Power Generation 181 -- 4.3. State of the Art Technologies 184 -- 4.4. Modeling the Wind Turbine Generators 200 -- 4.5. Fault Ride-Through Capability 223 -- 5. SHORT-CIRCUIT CURRENTS CALCULATION 229 -- Nouredine Hadjsaid, Ion TriSstiu, and Lucian Toma -- 5.1. Introduction 229 -- 5.2. Characteristics of Short-Circuit Currents 232 -- 5.3. Methods of Short-Circuit Currents Calculation 236 -- 5.4. Calculation of Short-Circuit Current Components 264 -- 6. ACTIVE POWER AND FREQUENCY CONTROL 291 -- Les Pereira -- 6.1. Introduction 291 -- 6.2. Frequency Deviations in Practice 293 -- 6.3. Typical Standards and Policies for "Active Power and Frequency Control" or "Load Frequency Control" 294 -- 6.4. System Modeling, Inertia, Droop, Regulation, and Dynamic Frequency Response 297 -- 6.5. Governor Modeling 302 -- 6.6. AGC Principles and Modeling 328 -- 6.7. Other Topics of Interest Related to Load Frequency Control 336 -- 7. VOLTAGE AND REACTIVE POWER CONTROL 340 -- Sandro Corsi and Mircea Eremia -- 7.1. Relationship Between Active and Reactive Powers and Voltage 342 -- 7.2. Equipments for Voltage and Reactive Power Control 347 -- 7.3. Grid Voltage and Reactive Power Control Methods 374.
7.4. Grid Hierarchical Voltage Regulation 399 -- 7.5. Implementation Study of the Secondary Voltage Regulation in Romania 423 -- 7.6. Examples of Hierarchical Voltage Control in the World 429 -- PART II POWER SYSTEM STABILITY AND PROTECTION 451 -- 8. BACKGROUND OF POWER SYSTEM STABILITY 453 -- S.S. (Mani) Venkata, Mircea Eremia, and Lucian Toma -- 8.1. Introduction 453 -- 8.2. Classification of Power Systems Stability 453 -- 8.3. Parallelism Between Voltage Stability and Angular Stability 469 -- 8.4. Importance of Security for Power System Stability 469 -- 9. SMALL-DISTURBANCE ANGLE STABILITY AND ELECTROMECHANICAL OSCILLATION DAMPING 477 -- Roberto Marconato and Alberto Berizzi -- 9.1. Introduction 477 -- 9.2. The Dynamic Matrix 478 -- 9.3. A General Simplified Approach 482 -- 9.4. Major Factors Affecting the Damping of Electromechanical Oscillations 501 -- 9.5. Damping Improvement 546 -- 9.6. Typical Cases of Interarea Or Low-Frequency Electromechanical Oscillations 564 -- 10. TRANSIENT STABILITY 570 -- Nikolai Voropai and Constantin Bulac -- 10.1. General Aspects 570 -- 10.2. Direct Methods for Transient Stability Assessment 572 -- 10.3. Integration Methods for Transient Stability Assessment 603 -- 10.4. Dynamic Equivalents 614 -- 10.5. Transient Stability Assessment of Large Electric Power Systems 638 -- 10.6. Application 645 -- 11. VOLTAGE STABILITY 657 -- Mircea Eremia and Constantin Bulac -- 11.1. Introduction 657 -- 11.2. System Characteristics and Load Modeling 658 -- 11.3. Static Aspects of Voltage Stability 667 -- 11.4. Voltage Instability Mechanisms: Interaction Between Electrical Network, Loads, and Control Devices 674 -- 11.5. Voltage Stability Assessment Methods 688 -- 11.6. Voltage Instability Countermeasures 716 -- 11.7. Application 724 -- 12. POWER SYSTEM PROTECTION 737 -- Klaus-Peter Brand and Ivan De Mesmaeker -- 12.1. Introduction 737 -- 12.2. Summary of IEC 61850 744 -- 12.3. The Protection Chain in Details 746 -- 12.4. Transmission and Distribution Power System Structures 753. 12.5. Properties of the Three-Phase Systems Relevant for Protection 755 -- 12.6. Protection Functions Sorted According to the Objects Protected 759 -- 12.7. From Single Protection Functions to System Protection 773 -- 12.8. Conclusions 780 -- PART III GRID BLACKOUTS AND RESTORATION PROCESS 787 -- 13. MAJOR GRID BLACKOUTS: ANALYSIS, CLASSIFICATION, AND PREVENTION 789 -- Yvon Besanger, Mircea Eremia, and Nikolai Voropai -- 13.1. Introduction 789 -- 13.2. Description of Some Previous Blackouts 792 -- 13.3. Analysis of Blackouts 835 -- 13.4. Economical and Social Effects 847 -- 13.5. Recommendations for Preventing Blackouts 849 -- 13.6. On Some Defense and Restoration Actions 850 -- 13.7. Survivability/vulnerability of Electric Power Systems 856 -- 13.8. Conclusions 860 -- 14. RESTORATION PROCESSES AFTER BLACKOUTS 864 -- Alberto Borghetti, Carlo Alberto Nucci, and Mario Paolone -- 14.1. Introduction 864 -- 14.2. Overview of The Restoration Process 865 -- 14.3. Black-Start-Up Capabilities of Thermal Power Plant: Modeling and Computer Simulations 869 -- 14.4. Description of Computer Simulators 888 -- 14.5. Concluding Remarks 896 -- 15. COMPUTER SIMULATION OF SCALE-BRIDGING TRANSIENTS IN POWER SYSTEMS 900 -- Kai Strunz and Feng Gao -- 15.1. Bridging of Instantaneous and Phasor Signals 901 -- 15.2. Network Modeling 903 -- 15.3. Modeling of Power System Components 909 -- 15.4. Application: Simulation of Blackout 923 -- References 926 -- Index 929. |
| Record Nr. | UNINA-9910829963503321 |
| Hoboken, New Jersey : , : John Wiley & Sons Inc., , [2013] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Handbook of electrical power system dynamics : modeling, stability, and control / / edited by Mircea Eremia, Mohammad Shahidehpour
| Handbook of electrical power system dynamics : modeling, stability, and control / / edited by Mircea Eremia, Mohammad Shahidehpour |
| Pubbl/distr/stampa | Hoboken, N.J., : John Wiley & Sons Inc., 2013 |
| Descrizione fisica | 1 online resource (975 p.) |
| Disciplina | 621.31 |
| Altri autori (Persone) |
EremiaMircea
ShahidehpourM. <1955-> |
| Collana | IEEE press series on power engineering |
| Soggetto topico |
Electric power system stability - Mathematical models
Electric power systems - Control Electric machinery - Dynamics |
| ISBN |
1-299-24203-0
1-118-51604-4 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Foreword xxiii -- Acknowledgments xxv -- Contributors xxvii -- 1. INTRODUCTION 1 -- Mircea Eremia and Mohammad Shahidehpour -- PART I POWER SYSTEM MODELING AND CONTROL 7 -- 2. SYNCHRONOUS GENERATOR AND INDUCTION MOTOR 9 -- Mircea Eremia and Constantin Bulac -- 2.1. Theory and Modeling of Synchronous Generator 9 -- 2.2. Theory and Modeling of the Induction Motor 114 -- 3. MODELING THE MAIN COMPONENTS OF THE CLASSICAL POWER PLANTS 137 -- Mohammad Shahidehpour, Mircea Eremia, and Lucian Toma -- 3.1. Introduction 137 -- 3.2. Types of Turbines 138 -- 3.3. Thermal Power Plants 143 -- 3.4. Combined-Cycle Power Plants 158 -- 3.5. Nuclear Power Plants 167 -- 3.6. Hydraulic Power Plants 169 -- 4. WIND POWER GENERATION 179 -- Mohammad Shahidehpour and Mircea Eremia -- 4.1. Introduction 179 -- 4.2. Some Characteristics of Wind Power Generation 181 -- 4.3. State of the Art Technologies 184 -- 4.4. Modeling the Wind Turbine Generators 200 -- 4.5. Fault Ride-Through Capability 223 -- 5. SHORT-CIRCUIT CURRENTS CALCULATION 229 -- Nouredine Hadjsaid, Ion TriSstiu, and Lucian Toma -- 5.1. Introduction 229 -- 5.2. Characteristics of Short-Circuit Currents 232 -- 5.3. Methods of Short-Circuit Currents Calculation 236 -- 5.4. Calculation of Short-Circuit Current Components 264 -- 6. ACTIVE POWER AND FREQUENCY CONTROL 291 -- Les Pereira -- 6.1. Introduction 291 -- 6.2. Frequency Deviations in Practice 293 -- 6.3. Typical Standards and Policies for "Active Power and Frequency Control" or "Load Frequency Control" 294 -- 6.4. System Modeling, Inertia, Droop, Regulation, and Dynamic Frequency Response 297 -- 6.5. Governor Modeling 302 -- 6.6. AGC Principles and Modeling 328 -- 6.7. Other Topics of Interest Related to Load Frequency Control 336 -- 7. VOLTAGE AND REACTIVE POWER CONTROL 340 -- Sandro Corsi and Mircea Eremia -- 7.1. Relationship Between Active and Reactive Powers and Voltage 342 -- 7.2. Equipments for Voltage and Reactive Power Control 347 -- 7.3. Grid Voltage and Reactive Power Control Methods 374.
7.4. Grid Hierarchical Voltage Regulation 399 -- 7.5. Implementation Study of the Secondary Voltage Regulation in Romania 423 -- 7.6. Examples of Hierarchical Voltage Control in the World 429 -- PART II POWER SYSTEM STABILITY AND PROTECTION 451 -- 8. BACKGROUND OF POWER SYSTEM STABILITY 453 -- S.S. (Mani) Venkata, Mircea Eremia, and Lucian Toma -- 8.1. Introduction 453 -- 8.2. Classification of Power Systems Stability 453 -- 8.3. Parallelism Between Voltage Stability and Angular Stability 469 -- 8.4. Importance of Security for Power System Stability 469 -- 9. SMALL-DISTURBANCE ANGLE STABILITY AND ELECTROMECHANICAL OSCILLATION DAMPING 477 -- Roberto Marconato and Alberto Berizzi -- 9.1. Introduction 477 -- 9.2. The Dynamic Matrix 478 -- 9.3. A General Simplified Approach 482 -- 9.4. Major Factors Affecting the Damping of Electromechanical Oscillations 501 -- 9.5. Damping Improvement 546 -- 9.6. Typical Cases of Interarea Or Low-Frequency Electromechanical Oscillations 564 -- 10. TRANSIENT STABILITY 570 -- Nikolai Voropai and Constantin Bulac -- 10.1. General Aspects 570 -- 10.2. Direct Methods for Transient Stability Assessment 572 -- 10.3. Integration Methods for Transient Stability Assessment 603 -- 10.4. Dynamic Equivalents 614 -- 10.5. Transient Stability Assessment of Large Electric Power Systems 638 -- 10.6. Application 645 -- 11. VOLTAGE STABILITY 657 -- Mircea Eremia and Constantin Bulac -- 11.1. Introduction 657 -- 11.2. System Characteristics and Load Modeling 658 -- 11.3. Static Aspects of Voltage Stability 667 -- 11.4. Voltage Instability Mechanisms: Interaction Between Electrical Network, Loads, and Control Devices 674 -- 11.5. Voltage Stability Assessment Methods 688 -- 11.6. Voltage Instability Countermeasures 716 -- 11.7. Application 724 -- 12. POWER SYSTEM PROTECTION 737 -- Klaus-Peter Brand and Ivan De Mesmaeker -- 12.1. Introduction 737 -- 12.2. Summary of IEC 61850 744 -- 12.3. The Protection Chain in Details 746 -- 12.4. Transmission and Distribution Power System Structures 753. 12.5. Properties of the Three-Phase Systems Relevant for Protection 755 -- 12.6. Protection Functions Sorted According to the Objects Protected 759 -- 12.7. From Single Protection Functions to System Protection 773 -- 12.8. Conclusions 780 -- PART III GRID BLACKOUTS AND RESTORATION PROCESS 787 -- 13. MAJOR GRID BLACKOUTS: ANALYSIS, CLASSIFICATION, AND PREVENTION 789 -- Yvon Besanger, Mircea Eremia, and Nikolai Voropai -- 13.1. Introduction 789 -- 13.2. Description of Some Previous Blackouts 792 -- 13.3. Analysis of Blackouts 835 -- 13.4. Economical and Social Effects 847 -- 13.5. Recommendations for Preventing Blackouts 849 -- 13.6. On Some Defense and Restoration Actions 850 -- 13.7. Survivability/vulnerability of Electric Power Systems 856 -- 13.8. Conclusions 860 -- 14. RESTORATION PROCESSES AFTER BLACKOUTS 864 -- Alberto Borghetti, Carlo Alberto Nucci, and Mario Paolone -- 14.1. Introduction 864 -- 14.2. Overview of The Restoration Process 865 -- 14.3. Black-Start-Up Capabilities of Thermal Power Plant: Modeling and Computer Simulations 869 -- 14.4. Description of Computer Simulators 888 -- 14.5. Concluding Remarks 896 -- 15. COMPUTER SIMULATION OF SCALE-BRIDGING TRANSIENTS IN POWER SYSTEMS 900 -- Kai Strunz and Feng Gao -- 15.1. Bridging of Instantaneous and Phasor Signals 901 -- 15.2. Network Modeling 903 -- 15.3. Modeling of Power System Components 909 -- 15.4. Application: Simulation of Blackout 923 -- References 926 -- Index 929. |
| Record Nr. | UNINA-9911018956703321 |
| Hoboken, N.J., : John Wiley & Sons Inc., 2013 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Power systems modelling and fault analysis [[electronic resource] ] : theory and practice / / Nasser D. Tleis
| Power systems modelling and fault analysis [[electronic resource] ] : theory and practice / / Nasser D. Tleis |
| Autore | Tleis Nasser D |
| Edizione | [1st edition] |
| Pubbl/distr/stampa | Oxford ; ; Burlington, MA, : Newnes, 2008 |
| Descrizione fisica | 1 online resource (650 p.) |
| Disciplina | 621.31015118 |
| Collana | Newnes power engineering series |
| Soggetto topico |
Electric power system stability - Mathematical models
Electric fault location - Mathematical models |
| Soggetto genere / forma | Electronic books. |
| ISBN |
1-281-07149-8
9786611071493 0-08-055427-X |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Front cover; Power systems modelling and fault analysis; Copyright page; Contents; List of electrical symbols; Foreword; Preface; Biography; Chapter 1 Introduction to power system faults; 1.1 General; 1.2 Structure of power systems; 1.3 Need for power system fault analysis; 1.3.1 General; 1.3.2 Health and safety considerations; 1.3.3 Design, operation and protection of power systems; 1.3.4 Design of power system equipment; 1.4 Characteristics of power system faults; 1.4.1 Nature of faults; 1.4.2 Types of faults; 1.4.3 Causes of faults; 1.4.4 Characterisation of faults
1.5 Terminology of short-circuit current waveform and current interruption 1.6 Effects of short-circuit currents on equipment; 1.6.1 Thermal effects; 1.6.2 Mechanical effects; 1.7 Per-unit analysis of power systems; 1.7.1 General; 1.7.2 Single-phase systems; 1.7.3 Change of base quantities; 1.7.4 Three-phase systems; 1.7.5 Mutually coupled systems having different operating voltages; 1.7.6 Examples; Chapter 2 Theory of symmetrical components and connection of phase sequence networks during faults; 2.1 General; 2.2 Symmetrical components of a three-phase power system 2.2.1 Balanced three-phase voltage and current phasors 2.2.2 Symmetrical components of unbalanced voltage or current phasors; 2.2.3 Apparent power in symmetrical component terms; 2.2.4 Definition of phase sequence component networks; 2.2.5 Sequence components of unbalanced three-phase impedances; 2.2.6 Sequence components of balanced three-phase impedances; 2.2.7 Advantages of symmetrical components frame of reference; 2.2.8 Examples; 2.3 Analysis of balanced and unbalanced faults in the sequence reference frame; 2.3.1 General; 2.3.2 Balanced three-phase to earth short-circuit faults 2.3.3 Balanced three-phase clear of earth short-circuit faults 2.3.4 Unbalanced one-phase to earth short-circuit faults; 2.3.5 Unbalanced phase-to-phase or two-phase short-circuit faults; 2.3.6 Unbalanced two-phase to earth short-circuit faults; 2.3.7 Unbalanced one-phase open-circuit faults; 2.3.8 Unbalanced two-phase open-circuit faults; 2.3.9 Example; 2.4 Fault analysis and choice of reference frame; 2.4.1 General; 2.4.2 One-phase to earth short-circuit faults; 2.4.3 Two-phase to earth short-circuit faults; 2.5 Analysis of simultaneous faults; 2.5.1 General 2.5.2 Simultaneous short-circuit faults at the same location 2.5.3 Cross-country faults or simultaneous faults at different locations; 2.5.4 Simultaneous open-circuit and short-circuit faults at the same location; 2.5.5 Simultaneous faults caused by broken and fallen to earth conductors; 2.5.6 Simultaneous short-circuit and open-circuit faults on distribution transformers; Further reading; Chapter 3 Modelling of multi-conductor overhead lines and cables; 3.1 General; 3.2 Phase and sequence modelling of three-phase overhead lines; 3.2.1 Background 3.2.2 Overview of the calculation of overhead line parameters |
| Record Nr. | UNINA-9910450696403321 |
Tleis Nasser D
|
||
| Oxford ; ; Burlington, MA, : Newnes, 2008 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Power systems modelling and fault analysis [[electronic resource] ] : theory and practice / / Nasser D. Tleis
| Power systems modelling and fault analysis [[electronic resource] ] : theory and practice / / Nasser D. Tleis |
| Autore | Tleis Nasser D |
| Edizione | [1st edition] |
| Pubbl/distr/stampa | Oxford ; ; Burlington, MA, : Newnes, 2008 |
| Descrizione fisica | 1 online resource (650 p.) |
| Disciplina | 621.31015118 |
| Collana | Newnes power engineering series |
| Soggetto topico |
Electric power system stability - Mathematical models
Electric fault location - Mathematical models |
| ISBN |
1-281-07149-8
9786611071493 0-08-055427-X |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Front cover; Power systems modelling and fault analysis; Copyright page; Contents; List of electrical symbols; Foreword; Preface; Biography; Chapter 1 Introduction to power system faults; 1.1 General; 1.2 Structure of power systems; 1.3 Need for power system fault analysis; 1.3.1 General; 1.3.2 Health and safety considerations; 1.3.3 Design, operation and protection of power systems; 1.3.4 Design of power system equipment; 1.4 Characteristics of power system faults; 1.4.1 Nature of faults; 1.4.2 Types of faults; 1.4.3 Causes of faults; 1.4.4 Characterisation of faults
1.5 Terminology of short-circuit current waveform and current interruption 1.6 Effects of short-circuit currents on equipment; 1.6.1 Thermal effects; 1.6.2 Mechanical effects; 1.7 Per-unit analysis of power systems; 1.7.1 General; 1.7.2 Single-phase systems; 1.7.3 Change of base quantities; 1.7.4 Three-phase systems; 1.7.5 Mutually coupled systems having different operating voltages; 1.7.6 Examples; Chapter 2 Theory of symmetrical components and connection of phase sequence networks during faults; 2.1 General; 2.2 Symmetrical components of a three-phase power system 2.2.1 Balanced three-phase voltage and current phasors 2.2.2 Symmetrical components of unbalanced voltage or current phasors; 2.2.3 Apparent power in symmetrical component terms; 2.2.4 Definition of phase sequence component networks; 2.2.5 Sequence components of unbalanced three-phase impedances; 2.2.6 Sequence components of balanced three-phase impedances; 2.2.7 Advantages of symmetrical components frame of reference; 2.2.8 Examples; 2.3 Analysis of balanced and unbalanced faults in the sequence reference frame; 2.3.1 General; 2.3.2 Balanced three-phase to earth short-circuit faults 2.3.3 Balanced three-phase clear of earth short-circuit faults 2.3.4 Unbalanced one-phase to earth short-circuit faults; 2.3.5 Unbalanced phase-to-phase or two-phase short-circuit faults; 2.3.6 Unbalanced two-phase to earth short-circuit faults; 2.3.7 Unbalanced one-phase open-circuit faults; 2.3.8 Unbalanced two-phase open-circuit faults; 2.3.9 Example; 2.4 Fault analysis and choice of reference frame; 2.4.1 General; 2.4.2 One-phase to earth short-circuit faults; 2.4.3 Two-phase to earth short-circuit faults; 2.5 Analysis of simultaneous faults; 2.5.1 General 2.5.2 Simultaneous short-circuit faults at the same location 2.5.3 Cross-country faults or simultaneous faults at different locations; 2.5.4 Simultaneous open-circuit and short-circuit faults at the same location; 2.5.5 Simultaneous faults caused by broken and fallen to earth conductors; 2.5.6 Simultaneous short-circuit and open-circuit faults on distribution transformers; Further reading; Chapter 3 Modelling of multi-conductor overhead lines and cables; 3.1 General; 3.2 Phase and sequence modelling of three-phase overhead lines; 3.2.1 Background 3.2.2 Overview of the calculation of overhead line parameters |
| Record Nr. | UNINA-9910777310303321 |
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Tleis Nasser D
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| Oxford ; ; Burlington, MA, : Newnes, 2008 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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