A generic DC grid model that is compatible with the standard AC s ystem stability model is presented and used to analyse the interaction between the DC grid and the host AC systems.

A multi-terminal DC (MTDC) grid interconnecting multiple AC systems and offshore energy sources (e.g. wind farms) across the nations and continents would allow effective sharing of intermittent renewable resources and open market operation for secure and cost-effective supply of electricity. However, such DC grids are unprecedented with no operational experience. Despite lots of discussions and specific visions for setting up such MTDC grids particularly in Europe, none has yet been realized in practice due to two major technical barriers:

Lack of proper understanding about the interaction between a MTDC grid and the surrounding AC systems.
Commercial unavailability of efficient DC side fault current interruption technology for conventional voltage sourced converter systems

This book addresses the first issue in details by presenting a comprehensive modeling, analysis and control design framework. Possible methodologies for autonomous power sharing and exchange of frequency support across a MTDC grid and their impact on overall stability is covered. An overview of the state-of-the-art, challenges and on-going research and development initiatives for DC side fault current interruption is also presented.

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Yes, you can access Multi-terminal Direct-Current Grids by Nilanjan Chaudhuri, Balarko Chaudhuri, Rajat Majumder, Amirnaser Yazdani in PDF and/or ePUB format, as well as other popular books in Technology & Engineering & Power Resources. We have over one million books available in our catalogue for you to explore.

Information

Publisher

Wiley-IEEE Press

Year

2014

ISBN

9781118960530

Edition

Topic

Technology & Engineering

Subtopic

Power Resources

Index

Technology & Engineering

Chapter 1
Fundamentals

1.1 Introduction

Commercial supply of electric power began in the late 1880s through electrification of the Wall Street area in New York City using direct current (DC) technology pioneered by Thomas Alva Edison. It was driven by the availability of DC generators and incandescent bulbs working with DC. Use of DC was the only option for electric supply until Nicola Tesla advocated for the use of alternating current (AC) form. Amidst fierce competition and lobbying for both DC and AC options, historically known as war of currents [1], AC started to win primarily due to more efficient power transmission enabled by use of transformers to step up or down voltage levels to reduce the power losses. As the need for long distance power transmission grew, the efficiency became a predominant consideration, which worked in favor of AC. For the first half of the twentieth century, AC transmission enjoyed unrivaled popularity and growth while DC was virtually ruled out for electric power transmission.

During the early 1950s, there was renewed interest in the use of DC technology primarily driven by the need for long distance cable transmission. It was realized that the power capacity of an AC cable reduces drastically due to excessive charging current even for moderate distances and voltage levels necessitating the use of DC cables where no such limitation exists. This led to the first DC cable link between mainland Sweden and Gotland island in 1953. Although DC reappeared in the scene in the context of cable transmission, it was soon realized that DC could be a cost-effective option even for overhead line transmission if the transmission distance is very high (beyond 1000 km) where AC transmission capacity is increasingly limited due to stability considerations.

Electric power generation and consumption continued to use AC, which meant converters were required at both ends to convert AC-to-DC and then DC-to-AC. At the beginning, these converters were based on mercury arc valves until the semiconductor switching devices like a thyrsitor was commercially available for high power applications. The converter technology evolved over time driving the costs down, which meant overhead DC transmission started to be cost-effective even for relatively small distances of the order of 700–900 km. This triggered a proliferation of long distance overhead DC links either embedded between two points within an AC system or interconnecting two separate AC systems. Alongside overhead DC lines, underground or subsea DC cables were also installed in different parts of the world. Until the late 1990s, high voltage directcurrent (HVDC) converter stations were built with either mercury-arc (before the seventies) or semiconductor switches, which could be turned on in a controllable way but relied on the polarity reversal of AC system voltage for turning off (or commutation). Over the years, the so-called line-commutated converter (LCC)-based HVDC technology got matured. Today, it constitutes the bulk of the installed and planned DC transmission capacity around the world.

It was only after 1997 that semiconductor switches with both controlled turn-on and turn-off capability, like an insulated gate bipolar transistor (IGBT) became commercially available at high power ratings. This enabled the use of voltage-sourced converter (VSC)-based HVDC technology, which offered significant advantages over its LCC counterpart. These include but are not limited to reliable operation with weak AC systems, low cost and footprint of converter stations, use of lighter, and stronger cables that makes VSC particularly attractive for offshore transmission. Despite the obvious potential and promise, the uptake of VSC technology was initially hindered by its limited power ratings (few hundred MWs) compared to LCC (up to 8000 MW). Rapid development in the VSC technology since has resulted in availability of relatively higher ratings (up to 1000 MW is under development now) for VSC-based HVDC links, but it is yet to catch up with the ratings offered by LCC.

Most of the HVDC links in operation today are connected between two points of a single AC system or two separate AC systems. These are commonly known as point-to-point HVDC links. There are only two exceptions around the world where the HVDC system has more than two points of connections to the AC system, which is referred to as multi-terminal direct current (MTDC) systems. Incidentally, both multi-terminal links in operation—Sardinia–Corsica–Italy link and Quebec–New England link—work with power flowing through the DC link from a generation center (e.g., hydro power from James Bay region in the north of Quebec province) to a main load center (e.g., Boston area and parts of New England) with another intermediate load center (e.g., Montreal region) on the way. However, unlike a meshed interconnected AC network, a truly meshed HVDC grid is yet to be realized in practice. For overhead lines, HVDC is cost-effective only at large transmission distances (e.g., above 600 km) at which level meshed interconnections are not economically justifiable. For underground or subsea cable transmission, the distance beyond which DC technology is effective is much shorter. This has resulted in a number of point-to-point interconnections between AC systems separated by sea to allow exchange of cost-effective electricity.

With increased penetration of intermittent renewable energy sources (e.g., wind power), balancing the supply and demand is likely to be a major problem. To ensure reliable operation of the system, there is a growing need for meshed interconnection to effectively share the diverse portfolio of renewable energy resources and thereby increase operational flexibility. For instance, in Europe, the hydropower from Norway and solar power in Spain and Portugal could be utilized when the wind is not blowing in the UK or mainland Europe and viceversa. To enable such sharing of power and also harness remote offshore wind, there is a business case for setting up an European Offshore Supergrid [2, 3, 4, 5]. There are several visions for an offshore grid in Europe, some of which are shown in Fig. 1.1. One aspect in common with all such visions is that several DC links are connected at a single point forming a DC grid.

**Figure 1.1** Visions for European Offshore Supergrid [2, 3, 4, 5].

Because of the subsea transmission distances involved, the only viable option is to use DC, which essentially calls for an MTDC or meshed grid. In such a meshed DC grid, the power flow in the DC links...

Cover
Title Page
Copyright
Dedication
Foreword
Preface
Acronyms
Symbols
Chapter 1: Fundamentals
Chapter 2: The Voltage-Sourced Converter (VSC)
Chapter 3: Modeling, Analysis, and Simulation of AC–MTDC Grids
Chapter 4: Autonomous Power Sharing
Chapter 5: Frequency Support
Chapter 6: Protection of MTDC Grids
References
Index
End User License Agreement