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access icon openaccess Research on sub-station-area breaker failure protection based on the principle of current differential

  • Author(s): Baowei Li 1, 2 ; Minghao Wen 1 ; Pengfei Lv 3 ; Junchao Zheng 1 ; Yaxin Su 2
    • View affiliations
  • Source: Volume 2019, Issue 16, March 2019, p. 1181 – 1184
    DOI:  10.1049/joe.2018.8819 , Online ISSN 2051-3305
This is an open access article published by the IET under the Creative Commons Attribution License (http://creativecommons.org/licenses/by/3.0/)
Received 29/08/2018, Accepted 19/09/2018, Published 23/10/2018

On the basis of the principle of breaker failure protection delay and the analysis of the main factors which affect the protection, a sub-station-area breaker failure and dead-zone protection technical scheme based on the current differential principle is proposed. In this scheme, an incomplete current differential protection is structured by the breakers current transformer (CT) of the non-fault area, which is adjacent to the fault area. When the criteria of the incomplete current differential protection are satisfied, the adjacent breakers will trip to realise the isolation of the fault. This scheme is not only affected by the CT tailing and CT saturation, but also greatly reduces the time delay of breaker failure protection and achieves the free protection setting. The implementation of the project adopts an expandable architecture designed with the master slave mode, which could be achieved by high reliability with a flexible configuration of engineering and not relying on external time signals. Moreover, this scheme has the advantages of versatility and easier to implement. Also, it is preferable due to practicability and extended significance to popularise.

Inspec keywords: substation protection; power transformer protection; circuit breakers; current transformers; relay protection; fault diagnosis; failure analysis; delays

Other keywords: CT saturation; nonfault area; CT tailing; free protection setting; fault area; master slave mode; fault isolation; CT; dead-zone protection technical scheme; adjacent breakers; breaker failure protection delay; incomplete current differential protection; substation-area breaker failure protection; current differential principle; breakers current transformer

Subjects: Transformers and reactors; Power system protection; Substations; Switchgear; Reliability

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