1st Edition
Flexible AC Transmission Systems (FACTS) Newton Power-Flow Modeling of Voltage-Sourced Converter-Based Controllers
Flexible AC Transmission Systems (FACTS): Newton Power-Flow Modeling of Voltage-Sourced Converter-Based Controllers introduces different voltage-sourced converter (VSC)-based FACTS controllers and VSC-based high-voltage direct current (VSC-HVDC) systems and their working principles, explaining how FACTS controllers exchange real and reactive power with systems.
Subsequently, the book:
- Describes the Newton–Raphson method and its application for solving the power-flow problem
- Presents the Newton power-flow modeling of the static synchronous series compensator (SSSC), unified power-flow controller (UPFC), interline power-flow controller (IPFC), generalized unified power-flow controller (GUPFC), and static synchronous compensator (STATCOM), accommodating the practical device constraint limits (because of the unique modeling strategy, the existing Newton power-flow codes can be reused)
- Develops a unified Newton power-flow model of AC systems incorporating multiterminal VSC-HVDC systems with pulse-width modulation (PWM) control schemes, directly yielding the VSC modulation indices from the power-flow solution
- Provides numerous case studies for validation of Newton power-flow models, elaborating on the occurrences and checking of unrealistic power-flow solutions in isolated cases
- Includes detailed derivations of all the difficult formulae as well as solved problems on typical VSC-based FACTS controllers
Flexible AC Transmission Systems (FACTS): Newton Power-Flow Modeling of Voltage-Sourced Converter-Based Controllers assumes at least an undergraduate-level understanding of engineering mathematics, network analysis, electrical machines, electrical power systems, and power electronics. Thus, the book provides a valuable reference for practitioners as well as senior-undergraduate and graduate students in electrical engineering and electrical power systems.
FACTS and FACTS Controllers
Introduction
The STATCOM
The SSSC
The UPFC
The IPFC and the GUPFC
Power-Flow Models of FACTS Controllers
VSC-HVDC Systems
Organization of the Book
Solved Problems
Introduction to the Newton–Raphson Method and the Power-Flow Problem
Introduction
The Newton–Raphson Method
The Power-Flow Problem
Power-Flow Equations
The Classification of Buses
Solution of the Power-Flow Problem
The Jacobian Matrix
Power-Flow Solution: The Generalized Form
Summary
Newton Power-Flow Model of the Static Synchronous Series Compensator
Introduction
SSSC Model for Newton Power-Flow Analysis
Power-Flow Equations in the Proposed SSSC Model
Implementation in Newton Power-Flow Analysis
Inclusion of SSSC Switching Losses
Case Studies and Results
Summary
Newton Power-Flow Model of the Unified Power-Flow Controller
Introduction
UPFC Model for Newton Power-Flow Analysis
Power-Flow Equations in the Proposed UPFC Model
Implementation in Newton Power-Flow Analysis
Accommodation of UPFC Device Limit Constraints
Selection of Initial Conditions
Case Studies and Results
Summary
Newton Power-Flow Model of the Interline Power-Flow Controller
Introduction
IPFC Model for Newton Power-Flow Analysis
Power-Flow Equations in the Proposed IPFC Model
Implementation in Newton Power-Flow Analysis
Accommodation of IPFC Device Limit Constraints
Selection of Initial Conditions
Case Studies and Results
Summary
Newton Power-Flow Model of the Generalized Unified Power-Flow Controller
Introduction
GUPFC Model for Newton Power-Flow Analysis
Power-Flow Equations in Proposed GUPFC Model
Implementation in Newton Power-Flow Analysis
Accommodation of GUPFC Device Limit Constraints
Selection of Initial Conditions
Case Studies and Results
Summary
Newton Power-Flow Model of the Static Compensator
Introduction
STATCOM Model for Newton Power-Flow Analysis
Power-Flow Equations in the Proposed STATCOM Model
Implementation in Newton Power-Flow Analysis
Accommodation of STATCOM Device Limit Constraints
Selection of Initial Conditions
Case Studies and Results
Summary
Newton Power-Flow Modeling of Voltage-Sourced Converter-Based HVDC Systems
Introduction
Modeling of the PTP VSC-HVDC
Newton Power-Flow Equations of the VSC-HVDC System
Case Studies and Results
Summary
Appendix: Derivations of Difficult Formulae
References
Biography
Suman Bhowmick, PhD, is an associate professor of electrical engineering in the Department of Electrical Engineering at Delhi Technological University (formerly Delhi College of Engineering), India. He has more than 23 years of experience in both industry and academia. He is also a member of the Institute of Electrical and Electronics Engineers (IEEE). His research interests include flexible AC transmission systems, voltage-sourced converter (VSC)-based high-voltage direct current (HVDC) systems, and their control.