Transient overvoltage suppression of LCC‐HVDC sending‐end system based on DC current control optimisation-Reference-Cited by-同舟云学术

Transient overvoltage suppression of LCC‐HVDC sending‐end system based on DC current control optimisation

Published:2024-05-09 Issue:2 Volume:6 Page:182-195
ISSN:2516-8401
Container-title:IET Energy Systems Integration
language:en
Short-container-title:IET Energy Syst Integration

Author:

Wang Yang¹,Zhu Jianhang²^ORCID,Li Yingbiao¹,Hu Jiabing¹,Ma Shicong³,Wang Tiezhu³

Affiliation:

1. School of Electrical and Electronic Engineering Huazhong University of Science and Technology Wuhan China

2. Department of Electrical and Electronic Engineering The University of Hong Kong Hong Kong SAR China

3. Power System Department China Electric Power Research Institute Beijing China

Abstract

AbstractThe receiving‐end system AC fault of the line‐commutated‐converter‐based high voltage direct current (LCC‐HVDC) will lead to commutation failure of the inverter side. During the fault and its recovery, AC transient low voltage and transient overvoltage (TOV) will occur in the sending‐end system. The TOV has the risk of triggering the disorderly off‐grid of the nearby renewable power generations. Besides, in a serious situation, it will threaten the power system to maintain a secure and steady operation. Therefore, the authors analyse the mechanism involved in the AC transient voltage during the AC fault and the recovery period first. It reveals that the key factor causing the TOV of the sending‐end system is the setting of the DC current reference value. Then, a DC current reference value limit method based on the AC TOV sampling value is proposed, which is used to accelerate DC current recovery and suppress the TOV of the sending‐end system. Finally, the effectiveness of the designed control method has been confirmed through electromagnetic transient simulations using the CIGRE HVDC benchmark model and a ±800 kV HVDC transmission system model situated in Northwest China.

Publisher

Institution of Engineering and Technology (IET)

Reference26 articles.

1. Research review of current‐source type actively commutated converter for high voltage direct current transmission systems;Li Z.;Proc. CSEE,2021

2. HVDC transient reactive power characteristics and impact of control system parameters during commutation failure and recovery;Tu J.;High Volt. Eng.,2017

3. Influence of UHV DC commutation failure on the transient reactive power characteristics of wind turbines in sending terminal grid;Nian H.;Proc. CSEE,2020

4. Commutation failure of UHVDC system for wind farm integration (part II): characteristics and mechanism analysis of transient reactive power and voltage of wind powers in sending terminal grid;Jin Y.;Proc. CSEE,2022