| Edition |
1st ed. |
| Description |
1 online resource |
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text txt rdacontent |
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computer c rdamedia |
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online resource cr rdacarrier |
| Note |
Includes index. |
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Print version record. |
| Summary |
Power System Small Signal Stability Analysis and Control presents a detailed analysis of the problem of severe outages due to the sustained growth of small signal oscillations in modern interconnected power systems. The ever-expanding nature of power systems and the rapid upgrade to smart grid technologies call for the implementation of robust and optimal controls. Power systems that are forced to operate close to their stability limit have resulted in the use of control devices by utility companies to improve the performance of the transmission system against commonly occurring power system disturbances. This book demonstrates how the application of power system damping controllers such as Power System Stabilizers (PSSs) and Flexible Alternating Current Transmission System (FACTS) controllers-namely Static Var Compensator (SVC) and Thyristor Controlled Series Compensator (TCSC)-can guard against system disruptions. Power System Small Signal Stability Analysis and Control examines the signal stability problem, providing an overview and analysis of the concepts and of the controllers used to mitigate it. Detailed mathematical derivations, illustrated case studies, the application of soft computation techniques, designs of robust controllers, and end-of-chapter exercises make it a useful resource to researchers, practicing engineers, and post-graduates in electrical engineering. |
| Bibliography |
Includes bibliographical references and index. |
| Contents |
Front Cover; Power System Small Signal Stability Analysis and Control; Copyright; Dedication; Contents; Acknowledgments; Author Biography; Preface; Chapter 1: Concepts of Small-Signal Stability; 1.1. Introduction; 1.2. Swing equation; 1.3. Nature of oscillations; 1.4. Modes of oscillations and its study procedure; 1.5. Synchronizing torque and damping torque; 1.6. Small-signal oscillations in a synchronous generator connected to an infinite bus; 1.7. An illustration; Solution; Exercises; References; Chapter 2: Fundamental Models of Synchronous Machine; 2.1. Introduction. |
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2.2. Synchronous machine dynamic model in the a-b-c reference frame2.3. Park's transformation and dynamic model in the d-q-o reference frame; 2.4. Per unit (PU) representation and scaling [2]; 2.5. Physical significance of PU system; 2.6. Stator flux-current relationships; 2.7. Rotor dynamic equations; 2.8. Reduced order model; 2.9. Equivalent circuit of the stator algebraic equations; 2.10. Synchronous machine exciter; 2.10.1. IEEE Type I exciter; 2.10.2. Static exciter; Exercises; References; Chapter 3: Models of Power Network and Relevant Power Equipments; 3.1. Introduction. |
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3.2. Simple model of a synchronous generator3.3. Steady-State Modeling of Synchronous Machine (Analytical Aspects) [1]; 3.4. Governor model [2]; 3.5. Turbine model [2]; 3.6. Power network model; 3.7. Modeling of load; 3.8. Power system stabilizer; 3.9. Model of FACTS devices; 3.9.1. Static Var compensator; 3.9.2. Static synchronous compensator; 3.9.3. Thyristor-controlled series compensator; 3.9.4. Static synchronous series compensator; 3.9.5. Unified power flow controller; Exercises; References; Chapter 4: Small-Signal Stability Analysis in SMIB Power System; 4.1. Introduction. |
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4.2. Heffron-Philips model of SMIB power system4.2.1. Fundamental equations; 4.2.2. Linearization process and state-space model; 4.2.3. Derivation of K constants: K1, K2, K3, K4, K5, and K6; 4.3. Small-Signal stability analysis using state-space model and block diagram; 4.4. An illustration; Solution; 4.5. Effect of Generator Field; Solution; 4.6. Effect of excitation system; 4.6.1. Effect of excitation system in torque-angle loop; 4.6.2. Calculation of steady-state synchronizing and damping torque; 4.6.3. Synchronizing and damping torque at rotor oscillation frequency; 4.7. An illustration. |
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SolutionExercises; References; Chapter 5: Small-Signal Stability Analysis in Multimachine System; 5.1. Introduction; 5.2. Multimachine small-Signal model; 5.2.1. Two-axis model of multimachine system; 5.2.2. Linearization process and multimachine state-space model; 5.2.3. Reduced-order flux-decay model; 5.3. Computation of initial conditions of the state variables; 5.3.1. An illustration; 5.4. Identification of electromechanical swing modes; 5.4.1. Participation factor analysis; Solution; 5.4.2. Swing mode and participation ratio; 5.5. An illustration: A test case; Exercises; References. |
| Subject |
Electric power system stability.
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Electric power systems -- Control.
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Réseaux électriques (Énergie) -- Stabilité.
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Réseaux électriques (Énergie) -- Régulation.
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TECHNOLOGY & ENGINEERING -- Mechanical.
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Electric power system stability
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Electric power systems -- Control
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| Added Author |
Chakrabarti, Abhijit, author.
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Sengupta, Aparajita, author.
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| Other Form: |
Print version: Mondal, Debasish. Power System Small Signal Stability Analysis and Control. Academic Press 2014 130671186X |
| ISBN |
9780128006702 (electronic bk.) |
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0128006706 (electronic bk.) |
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130671186X (electronic bk.) |
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9781306711869 (electronic bk.) |
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0128005726 |
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9780128005729 |
| Standard No. |
AU@ 000053138859 |
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AU@ 000065427814 |
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AU@ 000067073847 |
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CHBIS 010295305 |
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CHNEW 001012194 |
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CHVBK 327766883 |
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DEBBG BV042031112 |
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DEBBG BV042309777 |
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DEBSZ 414187016 |
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DEBSZ 414275519 |
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DEBSZ 431682135 |
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DEBSZ 475025113 |
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NLGGC 375358269 |
|
