DSCC-MMC STATCOM Main Circuit Parameters Design Considering Positive and Negative Sequence Compensation

Allan Fagner Cupertino; João Victor Matos Farias; Heverton Augusto Pereira; Seleme Isaac Seleme; Remus Teodorescu

doi:10.1007/s40313-017-0349-4

DSCC-MMC STATCOM Main Circuit Parameters Design Considering Positive and Negative Sequence Compensation

Allan Fagner Cupertino^*, João Victor Matos Farias, Heverton Augusto Pereira, Seleme Isaac Seleme, Remus Teodorescu

^*Corresponding author for this work

Research output: Contribution to journal › Journal article › Research › peer-review

22 Citations (Scopus)

Abstract

The double-star chopper cell modular multilevel converter (DSCC-MMC) has been employed in several applications as HVDC, energy storage, renewable energy, electrical drives and STATCOMs. Generally, the DSCC-MMC main circuit parameter design presented in literature considers balanced currents flowing through the converter. Nevertheless, in STATCOM application, the converter can compensate negative sequence components and unbalanced currents flow through the DSCC-MMC, resulting in different stresses in the converter phases. Therefore, this work presents a detailed design methodology of the DSCC-MMC main circuit parameters, considering both positive and negative sequence current compensations. The dc-link voltage, number of submodules, power semiconductor thermal stresses, submodule capacitance and arm inductances are designed. Expressions for the energy storage requirements are derived when negative sequence is compensated. A case study considering a 15-MVA STATCOM is presented, and simulation results validate the proposed design methodology. Finally, the converter power losses and thermal stresses in the power semiconductors are evaluated.

Original language	English
Journal	Journal of Control, Automation and Electrical Systems
Volume	29
Issue number	1
Pages (from-to)	62-74
Number of pages	13
ISSN	2195-3880
DOIs	https://doi.org/10.1007/s40313-017-0349-4
Publication status	Published - 1 Feb 2018

Keywords

Modular multilevel converter
Negative sequence compensation
Static synchronous compensator

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title = "DSCC-MMC STATCOM Main Circuit Parameters Design Considering Positive and Negative Sequence Compensation",

abstract = "The double-star chopper cell modular multilevel converter (DSCC-MMC) has been employed in several applications as HVDC, energy storage, renewable energy, electrical drives and STATCOMs. Generally, the DSCC-MMC main circuit parameter design presented in literature considers balanced currents flowing through the converter. Nevertheless, in STATCOM application, the converter can compensate negative sequence components and unbalanced currents flow through the DSCC-MMC, resulting in different stresses in the converter phases. Therefore, this work presents a detailed design methodology of the DSCC-MMC main circuit parameters, considering both positive and negative sequence current compensations. The dc-link voltage, number of submodules, power semiconductor thermal stresses, submodule capacitance and arm inductances are designed. Expressions for the energy storage requirements are derived when negative sequence is compensated. A case study considering a 15-MVA STATCOM is presented, and simulation results validate the proposed design methodology. Finally, the converter power losses and thermal stresses in the power semiconductors are evaluated.",

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DSCC-MMC STATCOM Main Circuit Parameters Design Considering Positive and Negative Sequence Compensation. / Cupertino, Allan Fagner; Farias, João Victor Matos; Pereira, Heverton Augusto et al.
In: Journal of Control, Automation and Electrical Systems, Vol. 29, No. 1, 01.02.2018, p. 62-74.

Research output: Contribution to journal › Journal article › Research › peer-review

TY - JOUR

T1 - DSCC-MMC STATCOM Main Circuit Parameters Design Considering Positive and Negative Sequence Compensation

AU - Cupertino, Allan Fagner

AU - Farias, João Victor Matos

AU - Pereira, Heverton Augusto

AU - Seleme, Seleme Isaac

AU - Teodorescu, Remus

PY - 2018/2/1

Y1 - 2018/2/1

N2 - The double-star chopper cell modular multilevel converter (DSCC-MMC) has been employed in several applications as HVDC, energy storage, renewable energy, electrical drives and STATCOMs. Generally, the DSCC-MMC main circuit parameter design presented in literature considers balanced currents flowing through the converter. Nevertheless, in STATCOM application, the converter can compensate negative sequence components and unbalanced currents flow through the DSCC-MMC, resulting in different stresses in the converter phases. Therefore, this work presents a detailed design methodology of the DSCC-MMC main circuit parameters, considering both positive and negative sequence current compensations. The dc-link voltage, number of submodules, power semiconductor thermal stresses, submodule capacitance and arm inductances are designed. Expressions for the energy storage requirements are derived when negative sequence is compensated. A case study considering a 15-MVA STATCOM is presented, and simulation results validate the proposed design methodology. Finally, the converter power losses and thermal stresses in the power semiconductors are evaluated.

AB - The double-star chopper cell modular multilevel converter (DSCC-MMC) has been employed in several applications as HVDC, energy storage, renewable energy, electrical drives and STATCOMs. Generally, the DSCC-MMC main circuit parameter design presented in literature considers balanced currents flowing through the converter. Nevertheless, in STATCOM application, the converter can compensate negative sequence components and unbalanced currents flow through the DSCC-MMC, resulting in different stresses in the converter phases. Therefore, this work presents a detailed design methodology of the DSCC-MMC main circuit parameters, considering both positive and negative sequence current compensations. The dc-link voltage, number of submodules, power semiconductor thermal stresses, submodule capacitance and arm inductances are designed. Expressions for the energy storage requirements are derived when negative sequence is compensated. A case study considering a 15-MVA STATCOM is presented, and simulation results validate the proposed design methodology. Finally, the converter power losses and thermal stresses in the power semiconductors are evaluated.

KW - Modular multilevel converter

KW - Negative sequence compensation

KW - Static synchronous compensator

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JO - Journal of Control, Automation and Electrical Systems

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ER -

DSCC-MMC STATCOM Main Circuit Parameters Design Considering Positive and Negative Sequence Compensation

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