This book provides an overview of power electronic converters for numerical simulations based on DIg SILENT Power Factory. It covers the working principles, key assumptions and implementation of models of different types of these power systems.
The book is divided into three main parts: the first discusses high-voltage direct currents, while the
second part examines distribution systems and micro-grids. Lastly, the third addresses the equipment and technologies used in modelling and simulation. Each chapter includes practical examples and exercises, and the accompanying software illustrates essential models, principles and performance using DIg SILENT Power Factory.
Exploring various current topics in the field of modelling power systems, this book will appeal to a variety of readers, ranging from students to practitioners.
Cuprins
Power Electronic modelling and simulations using DIg SILENT Power Factory.- Integration of Large Scale Photovoltaic Power Plants into Power Networks to Maintain System Stability.- Dynamic Modelling and Simulation of Power Electronic Converter in DIg-SILENT Simulation Language (DSL): Islanding Operation of Microgrid System with Multi Energy Sources.- Dynamic Modelling and Co-Simulation between Matlab-Simulink and DIg SILENT Power Factory of Electric Railway Traction Systems.- Transient Stability Assessment of Power System Incorporating DFIM-Based Pumped Storage Hydropower and Wind Farm.- Implementation of a Generic Type 3 Wind Turbine Model in DIg SILENT Power Factory.- Battery Energy Storage System Modelling in DIg SILENT Power Factory.- A benchmark test system for the power system stability assess-ment considering very high penetration of converter based generation units including grid forming converters.- System protection schemes as a way to prevent bottlenecks of the power system considering the Integration of Ofshore and onshore wind turbines and HVDC link.- Implementation and performance comparison of derivative and virtual synchronous power methods for enhancement of system frequency stability.- Modelling and simulation of wind turbines with grid forming direct voltage control and black-start capability.- Generic Modelling of PEM Technologies for Power System Stability Studies Based on Power Factory.- PST-17 Benchmark Power System DSL-based model with 90% Power Electronic Interfaced Generation with Black-Start and Grid Restoration capabilities in DIg SILENT Power Factory.- Applications of Power Factory for the study of basic notions of power system dynamics in graduate courses.
Despre autor
Prof Francisco M. Gonzalez-Longatt received his Ph.D. from Universidad Central de Venezuela in 2008, and his master’s degree from Universidad Bicentenaria de Aragua in 1999. He has been working in academia since 1992, and is currently a Professor of Electrical Power Systems at the University of South-Eastern Norway. He is a member of various professional organisations, and is a Fellow of the Higher Education Academy and a senior member of the IEEE. He has been involved in several industrial research projects and consultancy worldwide. Further, he is the author or editor of numerous books (Spanish and English) and an associate editor of several leading journals.
Prof José Luis Rueda Torres received his Electrical Engineer Diploma with cum laude honours from Escuela Politécnica Nacional in 2004. In 2009, he received his Ph.D. degree in Electrical Engineering from the National University of San Juan, where he had studied with a scholarship from DAAD. In 2014, became an Assistant Professor of Intelligent Electrical Power Grids at the Department of Electrical Sustainable Energy, Technical University Delft, and was promoted to Associate Professor in 2018. He has taken part in various professional activities including chairing or vice-chairing multiple committees and working groups, being on conference boards, and working as an associate editor for the ‘Swarm and Evolutionary Computation Journal’. His current research interests include power system reliability and stability, modelling for steady-state and dynamic stability studies (off-line and real-time digital simulation), optimal control design and multi-energy systems.