A novel single‐phase grounding fault voltage full compensation topology based on antiphase transformer

A novel single‐phase grounding fault voltage full compensation topology based on antiphase transformer

Abstract Multi‐tap and multi‐capacitors type arc suppression coils are commonly used in distribution systems. Due to their low compensation accuracy and limited arc suppression capability, it is hardly to avoid personal safety accidents and wildfires absolutely. In this paper, a novel single‐phase g...

Full description

Bibliographic Details
Main Authors: Xiaobin Cai, Hongwen Liu, Xiaohui Huang, Chunhui Huang, Chenchao Chai, Fei Rong
Format: Article
Language:English
Published: Wiley 2021-10-01
Series:IET Generation, Transmission & Distribution
Online Access:https://doi.org/10.1049/gtd2.12225
id doaj-cde87684d3c045c292c5ecfbc9652d7f
record_format Article
spelling doaj-cde87684d3c045c292c5ecfbc9652d7f2021-09-13T08:53:35ZengWileyIET Generation, Transmission & Distribution1751-86871751-86952021-10-0115202893290410.1049/gtd2.12225A novel single‐phase grounding fault voltage full compensation topology based on antiphase transformerXiaobin Cai0Hongwen Liu1Xiaohui Huang2Chunhui Huang3Chenchao Chai4Fei Rong5Electric Power Research Institute of Yunnan Power Grid Co., Ltd. Kunming Yunan Province 650217 ChinaElectric Power Research Institute of Yunnan Power Grid Co., Ltd. Kunming Yunan Province 650217 ChinaCollege of Electrical and Information Engineering Hunan University Changsha Hunan Province 410082 ChinaCollege of Electrical and Information Engineering Hunan University Changsha Hunan Province 410082 ChinaYunnan Megasun Technology Co., Ltd. Kunming Yunan Province 650217 ChinaCollege of Electrical and Information Engineering Hunan University Changsha Hunan Province 410082 ChinaAbstract Multi‐tap and multi‐capacitors type arc suppression coils are commonly used in distribution systems. Due to their low compensation accuracy and limited arc suppression capability, it is hardly to avoid personal safety accidents and wildfires absolutely. In this paper, a novel single‐phase grounding fault voltage full compensation topology based on antiphase transformer is proposed, which is composed by an antiphase transformer, a phase‐selection switch and a multi‐tap single‐phase voltage regulator. The proposed topology can control the neutral point voltage, thus cause the fault voltage being zero. By this way, the lack of arc suppression coil is overcome. The novel compensation topology features low costs, high precision of fault voltage compensation. The principle of the novel compensation topology is explained. The mathematical expressions of residual voltage and current are derived in detail. Finally, the simulation model and experimental platform were built. The results show that the proposed novel compensation topology can effectively make up for the shortcomings of traditional arc suppression coils when it is used with them.https://doi.org/10.1049/gtd2.12225
collection DOAJ
language English
format Article
sources DOAJ
author Xiaobin Cai
Hongwen Liu
Xiaohui Huang
Chunhui Huang
Chenchao Chai
Fei Rong
spellingShingle Xiaobin Cai
Hongwen Liu
Xiaohui Huang
Chunhui Huang
Chenchao Chai
Fei Rong
A novel single‐phase grounding fault voltage full compensation topology based on antiphase transformer
IET Generation, Transmission & Distribution
author_facet Xiaobin Cai
Hongwen Liu
Xiaohui Huang
Chunhui Huang
Chenchao Chai
Fei Rong
author_sort Xiaobin Cai
title A novel single‐phase grounding fault voltage full compensation topology based on antiphase transformer
title_short A novel single‐phase grounding fault voltage full compensation topology based on antiphase transformer
title_full A novel single‐phase grounding fault voltage full compensation topology based on antiphase transformer
title_fullStr A novel single‐phase grounding fault voltage full compensation topology based on antiphase transformer
title_full_unstemmed A novel single‐phase grounding fault voltage full compensation topology based on antiphase transformer
title_sort novel single‐phase grounding fault voltage full compensation topology based on antiphase transformer
publisher Wiley
series IET Generation, Transmission & Distribution
issn 1751-8687
1751-8695
publishDate 2021-10-01
description Abstract Multi‐tap and multi‐capacitors type arc suppression coils are commonly used in distribution systems. Due to their low compensation accuracy and limited arc suppression capability, it is hardly to avoid personal safety accidents and wildfires absolutely. In this paper, a novel single‐phase grounding fault voltage full compensation topology based on antiphase transformer is proposed, which is composed by an antiphase transformer, a phase‐selection switch and a multi‐tap single‐phase voltage regulator. The proposed topology can control the neutral point voltage, thus cause the fault voltage being zero. By this way, the lack of arc suppression coil is overcome. The novel compensation topology features low costs, high precision of fault voltage compensation. The principle of the novel compensation topology is explained. The mathematical expressions of residual voltage and current are derived in detail. Finally, the simulation model and experimental platform were built. The results show that the proposed novel compensation topology can effectively make up for the shortcomings of traditional arc suppression coils when it is used with them.
url https://doi.org/10.1049/gtd2.12225
work_keys_str_mv AT xiaobincai anovelsinglephasegroundingfaultvoltagefullcompensationtopologybasedonantiphasetransformer
AT hongwenliu anovelsinglephasegroundingfaultvoltagefullcompensationtopologybasedonantiphasetransformer
AT xiaohuihuang anovelsinglephasegroundingfaultvoltagefullcompensationtopologybasedonantiphasetransformer
AT chunhuihuang anovelsinglephasegroundingfaultvoltagefullcompensationtopologybasedonantiphasetransformer
AT chenchaochai anovelsinglephasegroundingfaultvoltagefullcompensationtopologybasedonantiphasetransformer
AT feirong anovelsinglephasegroundingfaultvoltagefullcompensationtopologybasedonantiphasetransformer
AT xiaobincai novelsinglephasegroundingfaultvoltagefullcompensationtopologybasedonantiphasetransformer
AT hongwenliu novelsinglephasegroundingfaultvoltagefullcompensationtopologybasedonantiphasetransformer
AT xiaohuihuang novelsinglephasegroundingfaultvoltagefullcompensationtopologybasedonantiphasetransformer
AT chunhuihuang novelsinglephasegroundingfaultvoltagefullcompensationtopologybasedonantiphasetransformer
AT chenchaochai novelsinglephasegroundingfaultvoltagefullcompensationtopologybasedonantiphasetransformer
AT feirong novelsinglephasegroundingfaultvoltagefullcompensationtopologybasedonantiphasetransformer
_version_ 1717381304622776320

Similar Items