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An Online Loop Closing Current Calculation Method for Complex Distribution Networks Considering Source and Load Uncertainties
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  • Weifeng Peng,
  • Licheng Sha,
  • Kaiyuan Zheng,
  • Shufeng Dong,
  • Xin Zhang,
  • Jing Tian
Weifeng Peng
Zhejiang University
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Licheng Sha
State Grid Beijing Electric Power Company
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Kaiyuan Zheng
State Grid Beijing Electric Power Company
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Shufeng Dong
Zhejiang University

Corresponding Author:[email protected]

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Xin Zhang
Zhejiang University
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Jing Tian
State Grid Beijing Electric Power Company
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Abstract

To address the challenges posed by frequent source and load fluctuations in existing loop closing current calculation methods, this paper proposes an online loop closing current calculation method that considers source and load uncertainties. First, a dual-stack dynamic monitoring system is utilized to obtain real-time voltage and current variations before and after disturbances. Second, Thevenin's theorem is employed to build an equivalent model of the distribution network, simplifying the complex network into a combination of an independent voltage source and a series impedance. Then, the steady-state loop closing current is calculated based on the open-circuit voltage and equivalent impedance at both sides of the loop closing point. Next, the optimal frequency method is applied to determine the equivalent impedance and attenuation time constant at a specific frequency, achieving accurate calculation of the transient loop closing current. Finally, simulations are conducted to model the fluctuations in distributed generation and load, analyzing the steady-state and transient loop closing currents. The simulation results demonstrate that the proposed method accurately captures the effects of source and load fluctuations on the loop closing current in dynamic environments, with minimal calculation error, indicating its high practicality.
12 Oct 2024Submitted to IET Generation, Transmission & Distribution
15 Oct 2024Submission Checks Completed
15 Oct 2024Assigned to Editor
15 Oct 2024Review(s) Completed, Editorial Evaluation Pending
26 Oct 2024Reviewer(s) Assigned
20 Nov 2024Editorial Decision: Revise Minor