Cascaded-and Modular-Multilevel Converter Laboratory Test System Options: A Review

Theodor Heath; Mike Barnes; Paul D. Judge; Geraint Chaffey; Phil Clemow; Tim C. Green; Peter R. Green; James Wylie; Georgios Konstantinou; Salvador Ceballos; Josep Pou; Mohamed M. Belhaouane; Haibo Zhang; Xavier Guillaud; Jack Andrews

doi:10.1109/ACCESS.2021.3066261

Cascaded-and Modular-Multilevel Converter Laboratory Test System Options: A Review

Theodor Heath, Mike Barnes, Paul D. Judge, Geraint Chaffey, Phil Clemow, Tim C. Green, Peter R. Green, James Wylie, Georgios Konstantinou, Salvador Ceballos, Josep Pou, Mohamed M. Belhaouane, Haibo Zhang, Xavier Guillaud, Jack Andrews

Research output: Contribution to journal › Article › peer-review

Abstract

The increasing importance of cascaded multilevel converters (CMCs), and the sub-category of modular multilevel converters (MMCs), is illustrated by their wide use in high voltage DC connections and in static compensators. Research is being undertaken into the use of these complex pieces of hardware and software for a variety of grid support services, on top of fundamental frequency power injection, requiring improved control for non-traditional duties. To validate these results, small-scale laboratory hardware prototypes are often required. Such systems have been built by many research teams around the globe and are also increasingly commercially available. Few publications go into detail on the construction options for prototype CMCs, and there is a lack of information on both design considerations and lessons learned from the build process, which will hinder research and the best application of these important units. This paper reviews options, gives key examples from leading research teams, and summarizes knowledge gained in the development of test rigs to clarify design considerations when constructing laboratory-scale CMCs.

Original language	English
Journal	IEEE Access
DOIs	https://doi.org/10.1109/ACCESS.2021.3066261
Publication status	Accepted/In press - 2021
Externally published	Yes

Bibliographical note

Publisher Copyright:
CCBYNCND

ASJC Scopus Subject Areas

General Computer Science
General Materials Science
General Engineering

Keywords

AC-DC power converters
Capacitors
Control systems
Hardware
HVDC transmission
HVDC transmission
Insulated gate bipolar transistors
Modular multilevel converters
Multilevel converters
Topology

Access to Document

10.1109/ACCESS.2021.3066261

Cite this

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title = "Cascaded-and Modular-Multilevel Converter Laboratory Test System Options: A Review",

abstract = "The increasing importance of cascaded multilevel converters (CMCs), and the sub-category of modular multilevel converters (MMCs), is illustrated by their wide use in high voltage DC connections and in static compensators. Research is being undertaken into the use of these complex pieces of hardware and software for a variety of grid support services, on top of fundamental frequency power injection, requiring improved control for non-traditional duties. To validate these results, small-scale laboratory hardware prototypes are often required. Such systems have been built by many research teams around the globe and are also increasingly commercially available. Few publications go into detail on the construction options for prototype CMCs, and there is a lack of information on both design considerations and lessons learned from the build process, which will hinder research and the best application of these important units. This paper reviews options, gives key examples from leading research teams, and summarizes knowledge gained in the development of test rigs to clarify design considerations when constructing laboratory-scale CMCs.",

keywords = "AC-DC power converters, Capacitors, Control systems, Hardware, HVDC transmission, HVDC transmission, Insulated gate bipolar transistors, Modular multilevel converters, Multilevel converters, Topology",

author = "Theodor Heath and Mike Barnes and Judge, {Paul D.} and Geraint Chaffey and Phil Clemow and Green, {Tim C.} and Green, {Peter R.} and James Wylie and Georgios Konstantinou and Salvador Ceballos and Josep Pou and Belhaouane, {Mohamed M.} and Haibo Zhang and Xavier Guillaud and Jack Andrews",

note = "Publisher Copyright: CCBYNCND",

year = "2021",

doi = "10.1109/ACCESS.2021.3066261",

language = "English",

journal = "IEEE Access",

issn = "2169-3536",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

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T2 - A Review

AU - Heath, Theodor

AU - Barnes, Mike

AU - Judge, Paul D.

AU - Chaffey, Geraint

AU - Clemow, Phil

AU - Green, Tim C.

AU - Green, Peter R.

AU - Wylie, James

AU - Konstantinou, Georgios

AU - Ceballos, Salvador

AU - Pou, Josep

AU - Belhaouane, Mohamed M.

AU - Zhang, Haibo

AU - Guillaud, Xavier

AU - Andrews, Jack

N1 - Publisher Copyright: CCBYNCND

PY - 2021

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AB - The increasing importance of cascaded multilevel converters (CMCs), and the sub-category of modular multilevel converters (MMCs), is illustrated by their wide use in high voltage DC connections and in static compensators. Research is being undertaken into the use of these complex pieces of hardware and software for a variety of grid support services, on top of fundamental frequency power injection, requiring improved control for non-traditional duties. To validate these results, small-scale laboratory hardware prototypes are often required. Such systems have been built by many research teams around the globe and are also increasingly commercially available. Few publications go into detail on the construction options for prototype CMCs, and there is a lack of information on both design considerations and lessons learned from the build process, which will hinder research and the best application of these important units. This paper reviews options, gives key examples from leading research teams, and summarizes knowledge gained in the development of test rigs to clarify design considerations when constructing laboratory-scale CMCs.

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KW - Modular multilevel converters

KW - Multilevel converters

KW - Topology

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Cascaded-and Modular-Multilevel Converter Laboratory Test System Options: A Review

Abstract

Bibliographical note

ASJC Scopus Subject Areas

Keywords

Access to Document

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