The Voltage Regulation Control Strategy with Distributed Photovoltaic Participation under Serious Failure Based on Transient Voltage Margin

The Voltage Regulation Control Strategy with Distributed Photovoltaic Participation under Serious Failure Based on Transient Voltage Margin

With the poor ability of distributed PV to withstand voltage fluctuation, the voltage fluctuation caused by DC blocking can lead to large-scale disorderly de-networking of distributed PV, especially those distributed PV which close to voltage weak buses. which means that more and more attentions are...

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Main Authors: Liu Yunxin, Yao Liangzhong, Liao Siyang, Xu Jian, Wu Di, Tang Wei, Yang Cheng
Format: Article
Language:English
Published: EDP Sciences 2020-01-01
Series:E3S Web of Conferences
Online Access:https://www.e3s-conferences.org/articles/e3sconf/pdf/2020/46/e3sconf_ceege2020_01002.pdf
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spelling doaj-3b3b7de32e2f42eb805f433826a919102021-04-02T09:18:20ZengEDP SciencesE3S Web of Conferences2267-12422020-01-011860100210.1051/e3sconf/202018601002e3sconf_ceege2020_01002The Voltage Regulation Control Strategy with Distributed Photovoltaic Participation under Serious Failure Based on Transient Voltage MarginLiu Yunxin0Yao Liangzhong1Liao Siyang2Xu Jian3Wu Di4Tang Wei5Yang Cheng6the School of Electrical Engineering and Automation, Wuhan Universitythe School of Electrical Engineering and Automation, Wuhan Universitythe School of Electrical Engineering and Automation, Wuhan Universitythe School of Electrical Engineering and Automation, Wuhan Universitythe State Grid, Anhui Provincial Electric Power Companythe State Grid, Anhui Provincial Electric Power Companythe State Grid, Anhui Provincial Electric Power CompanyWith the poor ability of distributed PV to withstand voltage fluctuation, the voltage fluctuation caused by DC blocking can lead to large-scale disorderly de-networking of distributed PV, especially those distributed PV which close to voltage weak buses. which means that more and more attentions are paid to the transient voltage stability (TVS). If distributed PV can participation in reactive compensation, we don’t need to add additional reactive power compensator, voltage stability of voltage weak buses will be increased, which can reduce PV off-grid. Therefore, for the HVDC receiving end system under distributed PV intensive access, first of all, we need to find the voltage weak bus, then increase the reactive power output of distributed PV near the voltage weak buses to increase transient voltage margin. Taking the simplified model of power system in Anhui Province as an example, the validity of the strategy is verified, and the results show that the transient voltage stability of the system has been improved.https://www.e3s-conferences.org/articles/e3sconf/pdf/2020/46/e3sconf_ceege2020_01002.pdf
collection DOAJ
language English
format Article
sources DOAJ
author Liu Yunxin
Yao Liangzhong
Liao Siyang
Xu Jian
Wu Di
Tang Wei
Yang Cheng
spellingShingle Liu Yunxin
Yao Liangzhong
Liao Siyang
Xu Jian
Wu Di
Tang Wei
Yang Cheng
The Voltage Regulation Control Strategy with Distributed Photovoltaic Participation under Serious Failure Based on Transient Voltage Margin
E3S Web of Conferences
author_facet Liu Yunxin
Yao Liangzhong
Liao Siyang
Xu Jian
Wu Di
Tang Wei
Yang Cheng
author_sort Liu Yunxin
title The Voltage Regulation Control Strategy with Distributed Photovoltaic Participation under Serious Failure Based on Transient Voltage Margin
title_short The Voltage Regulation Control Strategy with Distributed Photovoltaic Participation under Serious Failure Based on Transient Voltage Margin
title_full The Voltage Regulation Control Strategy with Distributed Photovoltaic Participation under Serious Failure Based on Transient Voltage Margin
title_fullStr The Voltage Regulation Control Strategy with Distributed Photovoltaic Participation under Serious Failure Based on Transient Voltage Margin
title_full_unstemmed The Voltage Regulation Control Strategy with Distributed Photovoltaic Participation under Serious Failure Based on Transient Voltage Margin
title_sort voltage regulation control strategy with distributed photovoltaic participation under serious failure based on transient voltage margin
publisher EDP Sciences
series E3S Web of Conferences
issn 2267-1242
publishDate 2020-01-01
description With the poor ability of distributed PV to withstand voltage fluctuation, the voltage fluctuation caused by DC blocking can lead to large-scale disorderly de-networking of distributed PV, especially those distributed PV which close to voltage weak buses. which means that more and more attentions are paid to the transient voltage stability (TVS). If distributed PV can participation in reactive compensation, we don’t need to add additional reactive power compensator, voltage stability of voltage weak buses will be increased, which can reduce PV off-grid. Therefore, for the HVDC receiving end system under distributed PV intensive access, first of all, we need to find the voltage weak bus, then increase the reactive power output of distributed PV near the voltage weak buses to increase transient voltage margin. Taking the simplified model of power system in Anhui Province as an example, the validity of the strategy is verified, and the results show that the transient voltage stability of the system has been improved.
url https://www.e3s-conferences.org/articles/e3sconf/pdf/2020/46/e3sconf_ceege2020_01002.pdf
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