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Fault mitigation mechanism to pave the way to accommodate over 90% renewable energy in electric power systems

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  • Li, Canbing
  • Chen, Dawei
  • Liu, Xubin
  • Shahidehpour, Mohammad
  • Yang, Hanyu
  • Liu, Hui
  • Huang, Wentao
  • Wang, Jianxiao
  • Deng, Xiang
  • Zhang, Qiying

Abstract

Renewable energy plays a key role in reducing carbon emissions. The electric power system is widely considered a platform to accommodate renewable energy because of the high efficiency in transmitting energy through electricity tie lines. However, most renewable energy generation is weather-dependent, bringing difficulties in balancing generations and electricity demands. There are two major solutions to address the imbalance problem. The first is to balance the fluctuation of renewable energy in time scales by deploying energy storage, but with huge costs and security risks. The other is to balance the fluctuation in spatial scales by enhancing the interconnection among electric power systems, which however results in a sharp increase in the fault current in many countries. The high level of fault current threatens the security of power system. In other words, the overrating fault current of electric power systems is one of the key bottlenecks for carbon neutrality. To mitigate the high-level fault current because of the interconnection, we propose a novel mechanism, namely fault current release. It achieves new functionalities with proven equipment at low cost and will create no impact on the electric power systems in normal operation. The simulation selected six representative electric power systems, including those in the USA, the UK, China, Brazil, Nigeria and IEEE reliable test system. Results show that the fault current release method enables an increase of renewable energy accommodation from 19.2% ∼ 47.2% to over 90%, much higher than the existing methods can do. Correspondingly, the emissions of CO2, NOX and SOX in these systems decrease by 67.84% ∼ 88.07%, 61.17% ∼ 88.24% and 58.25% ∼ 88.33%, respectively. The proposed method is also economical in that it can accommodate renewable energy at about one-tenth the cost of energy storage. Our findings hence suggest a promising way to build a carbon-free energy system.

Suggested Citation

  • Li, Canbing & Chen, Dawei & Liu, Xubin & Shahidehpour, Mohammad & Yang, Hanyu & Liu, Hui & Huang, Wentao & Wang, Jianxiao & Deng, Xiang & Zhang, Qiying, 2024. "Fault mitigation mechanism to pave the way to accommodate over 90% renewable energy in electric power systems," Applied Energy, Elsevier, vol. 359(C).
  • Handle: RePEc:eee:appene:v:359:y:2024:i:c:s0306261924000060
    DOI: 10.1016/j.apenergy.2024.122623
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    1. Chen, Qun & Meng, Nan & He, Ke-Lun & Ma, Huan & Gou, Xing, 2024. "Multi-time scale operation optimization of integrated power and thermal system considering load disturbance," Energy, Elsevier, vol. 302(C).

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