Dynamics and control of electric transmission and microgrids

Dynamics and control of electric transmission and microgrids / K.R. Padiyar, Anil M. Kulkarni.

"Highlights the role of transmission and distribution grids that ensure the reliability and quality of electric power supply. - Original coverage of Analysis and Control of Loss of Synchronism including, Extended Equal Area Criterion (EEAC). - Timely and unique coverage of On-Line Detection of...

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Bibliographic Details
Main Authors: Padiyar, K. R. (Author), Kulkarni, Anil M. (Author)
Format: eBook
Language:English
Published: Hoboken, NJ : John Wiley & Sons, Inc., 2019.
Subjects:
Electric power systems > Control.
Electric power transmission.
Microgrids (Smart power grids)
TECHNOLOGY & ENGINEERING > Mechanical.
Electric power systems > Control
Electric power transmission
Online Access:Click for online access
Table of Contents:
  • Cover; Table of Contents; Preface; Acknowledgements; 1 Introduction; 1.1 Present Status of Grid Operation; 1.2 Overview of System Dynamics and Control; 1.3 Monitoring and Enhancing System Security; 1.4 Emergency Control and System Protection; 1.5 Recent Developments; 1.6 Outline of Chapters; References; 2 Grid Characteristics and Operation; 2.1 Description of Electric Grids; 2.2 Detailed Modeling of Three-Phase AC Lines [3]; 2.3 Circuit Models of Symmetric Networks; 2.4 Network Equations in and Components [4-7]; 2.5 Frequency and Power Control [8-11]; 2.6 Dynamic Characteristics of AC Grids
  • 2.7 Control of Power Flow in AC Grids [14, 16]2.8 Analysis of Electromagnetic Transients; 2.9 Transmission Expansion Planning [18]; 2.10 Reliability in Distribution Systems [19]; 2.11 Reliable Power Flows in a Transmission Network; 2.12 Reliability Analysis of Transmission Networks; 2.A Analysis of a Distributed Parameter Single-Phase Line in Steady State; 2.B Computation of Electrical Torque; References; 3 Modeling and Simulation of Synchronous Generator Dynamics; 3.1 Introduction; 3.2 Detailed Model of a Synchronous Machine; 3.3 Park's Transformation [7]; 3.4 Per-Unit Quantities
  • 3.5 Equivalent Circuits of a Synchronous Machine3.6 Synchronous Machine Models for Stability Analysis; 3.7 An Exact Circuit Model of a Synchronous Machine for Electromagnetic Transient Analysis [14]; 3.8 Excitation and Prime Mover Controllers; 3.9 Transient Instability due to Loss of Synchronism; 3.10 Extended Equal Area Criterion; 3.11 Dynamics of a Synchronous Generator; Network Equations; Calculation of Initial Conditions; System Simulation; 3.A Derivation of Electrical Torque; References; 4 Modeling and Simulation of Wind Power Generators; 4.1 Introduction
  • 4.2 Power Extraction by Wind Turbines4.3 Generator and Power Electronic Configurations; 4.4 Modeling of the Rotating System; 4.5 Induction Generator Model; 4.7 Control of Type III WTG System; 4.8 Control of Type IV WTG System; References; 5 Modeling and Analysis of FACTS and HVDC Controllers; 5.1 Introduction; 5.2 FACTS Controllers [3-5]; 5.3 Reactive Power Control [5, 8]; Control Characteristics; 5.4 Thyristor-Controlled Series Capacitor; 5.5 Static Synchronous Compensator; 5.6 HVDC Power Transmission [17-21]; 5.A Case Study of a VSC-HVDC Link [31]; References; 6 Damping of Power Swings
  • 6.1 Introduction6.2 Origin of Power Swings; 6.3 SMIB Model with Field Flux Dynamics and AVR; 6.4 Damping and Synchronizing Torque Analysis; 6.5 Analysis of Multi-Machine Systems; 6.6 Principles of Damping Controller Design [16]; 6.7 Concluding Remarks; 6.A Eigenvalues of the Stiffness matrix of Section 6.5.1; 6.B Three-Machine System Data; References; 7 Analysis and Control of Loss of Synchronism; 7.1 Introduction; 7.2 Effect of LoS; 7.3 Understanding the LoS Phenomenon; 7.4 Criteria for Assessment of Stability; 7.5 Power System Modeling and Simulation for Analysis of LoS

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