Review on multi-level voltage source converter based HVDC technologies for grid connection of large offshore wind farms

With the ultimate aim to remove/reduce constraints on the amount of non-synchronous generators that may be connected to power systems, this paper identifies potential problems associated with system dynamics under high penetrations of converter-interfaced sources, especially from the perspective of inertia and responses to disturbances. The configuration of VSC-HVDC transmission systems and their controllers is introduced and analysed. Methods that have been proposed to enable VSC-HVDC systems to provide frequency response are reviewed, and a typical VSC-HVDC system with an associated control system is built and validated in Matlab Simulink. These models will form a key part of a modelling toolkit that is being developed to investigate optimal methods for reducing (or removing) future Non-Synchronous Generation (NSG) penetration constraints in the power system in the UK, which represents further work that will be conducted in this project

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“…Furthermore, there are other advantages of HVDC,, particularly with respect to power system stability [15][16][17][18]:…”

Section: A Motivation For Development Of Vsc-hvdcmentioning

confidence: 99%

A review of control methods for providing frequency response in VSC-HVDC transmission systems

Booth

Roscoe

et al. 2014

2014 49th International Universities Power Engineering Conference (UPEC)

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“…Amplitude of the second-frequency common-mode energy On the other hand, the energy oscillation of each capacitor can also be represent as 2 2 c ( m a x ) ( m i n ) ( a v g ) ( p p )…”

Section: Analysis Of the Common-mode Capacitor Voltage Fluctuatiomentioning

confidence: 99%

“…Compared with traditional power topologies, MMC has the advantages of high efficiency, low semiconductor stresses, small rate of rise in voltage, excellent waveform quality, and the capability of handling very high voltage (up to hundreds of kilo-volts). As such, MMC is regarded as the most attractive topology for high-voltage large-volume applications, and has already achieved great success in the field of HVDC power transmissions [2]. At the same time, MMC also has the potential for the application of high-voltage motor drives.…”

Section: Introductionmentioning

confidence: 99%

Suppression scheme for the common-mode capacitor voltage fluctuations in modular multilevel converters

Zhang

et al. 2014

2014 International Power Electronics and Application Conference and Exposition

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In the very recent years, the modular multilevel converter (MMC) topology has become the development trend of high-voltage high-power power conversion technologies. However, one specific issue associated with MMC is the necessity of very large capacitances, which stops it from reducing cost, increasing reliability, and improving power density. To reduce the capacitance of required capacitors, in this paper, the nature of the common-mode capacitor voltage fluctuation is analyzed, and the corresponding suppression scheme based on a proportionalintegral plus resonant (PI+R) controller is proposed. Compared with conventional open-loop suppression methods, the control accuracy, flexibility, and robustness can be significantly improved. Finally, the validity and effectiveness of the proposed scheme are verified by simulation and experimental results.

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“…These higher level topologies have the following advantages: The three manufacturers of VSC HVDC (ABB, Alstom Grid and Siemens) have recently moved towards the multi-level converter topology, each different on a power electronic level, but operating in a similar manner towards the AC and DC grid side. These different implementations of VSC converters are described in more detail in respectively Jacobson (2010), Alstom Grid (2011) and Dorn (2008), and a review comparing them is provided in Glasdam (2012) and Ahmed (2011). In this chapter, only a short description of the different topologies and their schematics is given.…”

Section: Vsc Convertermentioning

confidence: 99%

High Voltage Direct Current (HVDC) electric power transmission systems

Hertem

Delimar

2013

Electricity Transmission, Distribution and Storage Systems

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Review on multi-level voltage source converter based HVDC technologies for grid connection of large offshore wind farms

Cited by 74 publications

References 34 publications

A review of control methods for providing frequency response in VSC-HVDC transmission systems

A review of control methods for providing frequency response in VSC-HVDC transmission systems

Suppression scheme for the common-mode capacitor voltage fluctuations in modular multilevel converters

High Voltage Direct Current (HVDC) electric power transmission systems

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