A negative sequence current injection (NSCI)-based active protection scheme for islanded microgrids

•A novel active protection scheme for islanded microgrids.•Relay identifies the fault direction by the current increment between pre-injection and current generation steady states.•A non-communication scheme & only one distributed generator is dedicated to injecting current without location limi...

Full description

Saved in:
Bibliographic Details
Published in:International journal of electrical power & energy systems 2024-07, Vol.158, p.109965, Article 109965
Main Authors: Yang, Zhenkun, Dyśko, Adam, Egea-Àlvarez, Agustí
Format: Article
Language:English
Subjects:
Active protection method
Fault direction indicator
High impedance fault
Microgrid
Negative sequence current injection
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•A novel active protection scheme for islanded microgrids.•Relay identifies the fault direction by the current increment between pre-injection and current generation steady states.•A non-communication scheme & only one distributed generator is dedicated to injecting current without location limitation.•The excellent performance under unbalanced faults is not affected by load distribution or synchronous machine.•Comparative study of proposed scheme with other microgrid protection methods. The growing penetration of converter interfaced generation creates unprecedented challenges to protection strategies at all voltage levels. This paper proposes a novel Negative Sequence Current Injection (NSCI)-based active protection scheme for islanded microgrids. The faulty section identification method based on the negative sequence current increment between the pre-injection and current generation steady state conditions enables the scheme to achieve an excellent High Impedance Fault (HIF) detection capability. The proposed NSCI control algorithm maintains the phase angle of the negative sequence current fixed during injection progress, thus providing a highly discriminative feature which facilitates the correct identification of the faulty section. As no form of communication is required the proposed protection scheme can be very cost-effective and flexible in practical applications. Following the detailed description of the principle of operation and the setting procedure, a systematic simulation-based validation is undertaken considering a variety of influencing factors such as fault type, resistance and position, as well as impact of load distribution under HIFs, and possible presence of Synchronous Generators (SGs). The results show that the scheme has an excellent detection and discrimination ability, especially during unbalanced faults, and is not affected by load distribution or behaviour of other sources, including SG.
ISSN:0142-0615
1879-3517
DOI:10.1016/j.ijepes.2024.109965