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access icon openaccess Researches on grounding modes of the AC/DC hybrid system with various distributed renewable energy

  • Author(s): Qi Xu 1 ; Jianzong He 2 ; Songbo Huang 1 ; Jie Zeng 1 ; Chunju Fan 3 ; Wei Wang 1
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  • Source: Volume 2019, Issue 16, March 2019, p. 3035 – 3038
    DOI:  10.1049/joe.2018.8387 , Online ISSN 2051-3305
This is an open access article published by the IET under the Creative Commons Attribution-NonCommercial-NoDerivs License (http://creativecommons.org/licenses/by-nc-nd/3.0/)
Received 22/08/2018, Accepted 19/09/2018, Published 29/10/2018

With the considerable demand for distributed renewable energy and the significant increase of generalised DC loads, such as IT equipment, DC air-conditioner, electric vehicle, the traditional AC distribution network is no longer efficient. Driven by the rapid development of power electronics technology, the AC/ DC hybrid system is an effective way for large capacity AC/DC sources and loads efficient integrated. To ensure the stable operation of AC/DC hybrid system, the grounding mode analysis is necessary, which is the precondition for overvoltage analysis, lightning arrester configuration, and protection design. To select grounding mode of AC/DC hybrid system, the detailed system structure scheme is first determined considering the factors such as integrated object, reliability requirement, capacity of sources and loads, and converter type. Then the main connection scheme is selected considering the principle of line insulation, economy, and reliability. Based on the system structure and main connection scheme, a suitable grounding mode is selected for the AC/DC hybrid system with various distributed renewable energy, by weighing various factors such as power supply reliability, protection sensitivity, insulation level, and personal safety.

Inspec keywords: power electronics; distributed power generation; overvoltage protection; lightning protection; power distribution reliability; renewable energy sources; arresters

Other keywords: generalised DC loads; overvoltage analysis; lightning arrester configuration; AC/DC hybrid system; power electronics technology; traditional AC distribution network; line insulation; grounding mode analysis; protection design; distributed renewable energy

Subjects: Distributed power generation; Power convertors and power supplies to apparatus; Protection apparatus; Energy resources; Distribution networks; Reliability

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