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Distributed Consensus Hierarchical Optimization and Control Method for Integrated Energy System Based on Event-Triggered Mechanism

Author

Listed:
  • Jun Ye

    (Shanghai Electric Power Engineering Co., Ltd., Shanghai 200025, China)

  • Bo Liu

    (Shanghai Electric Power Engineering Co., Ltd., Shanghai 200025, China)

  • Zhiqiang Yuan

    (Shanghai Electric Power Engineering Co., Ltd., Shanghai 200025, China)

  • Yunhui Chen

    (Shanghai Electric Power Engineering Co., Ltd., Shanghai 200025, China)

  • Yufei Wang

    (School of Electric Power Engineering, Shanghai University of Electric Power, Shanghai 200090, China)

  • Hua Xue

    (School of Electric Power Engineering, Shanghai University of Electric Power, Shanghai 200090, China)

  • Chen Ling

    (School of Electric Power Engineering, Shanghai University of Electric Power, Shanghai 200090, China)

  • Kening Zhang

    (School of Electric Power Engineering, Shanghai University of Electric Power, Shanghai 200090, China)

Abstract

For integrated energy systems (IES) composed of a set of energy hubs (EHs), a consensus control method is usually adopted to achieve accurate sharing of electrical and thermal composite energies. To solve the communication redundancy problem of the consensus control method, a hierarchical optimization and distributed control scheme based on a dynamic event-triggered mechanism of EHs is proposed to realize stable operation of IES. An economic optimization strategy based on equal increment principle is improved to minimize the operation costs of IES in the second layer. Due to consensus control being integrated into the supply-demand power deviation calculations of EHs, the desired electrical and thermal power trajectories are accurately determined. To improve dynamic response performances in the presence of uncertain disturbances, an event-triggered communication mechanism is designed in the primary layer. The triggering threshold can be adjusted dynamically according to changes of electrical and thermal power outputs, and the redundant communication requirement in the electrical branches is reduced. Considering the coupling characteristics of IES energy networks, a consensus control method is promoted to synchronously track the desired electric and thermal power trajectories of EHs, and the goal of accurate power sharing is achieved. The frequency and pipeline pressure fluctuations are also limited within the allowable range. The economic optimization and coordinated operation of electrical and thermal composite energies in IES are guaranteed by the proposed hierarchical control structure. Additionally, only information from neighboring EHs at the event-triggered time is involved, so the computation simplicity and control performance can be obtained simultaneously. The hardware-in-loop experimental results are conducted to demonstrate the effectiveness of the proposed control strategy.

Suggested Citation

  • Jun Ye & Bo Liu & Zhiqiang Yuan & Yunhui Chen & Yufei Wang & Hua Xue & Chen Ling & Kening Zhang, 2023. "Distributed Consensus Hierarchical Optimization and Control Method for Integrated Energy System Based on Event-Triggered Mechanism," Energies, MDPI, vol. 16(13), pages 1-19, July.
    • Handle: RePEc:gam:jeners:v:16:y:2023:i:13:p:5146-:d:1186233
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    References listed on IDEAS

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    1. Ayele, Getnet Tadesse & Haurant, Pierrick & Laumert, Björn & Lacarrière, Bruno, 2018. "An extended energy hub approach for load flow analysis of highly coupled district energy networks: Illustration with electricity and heating," Applied Energy, Elsevier, vol. 212(C), pages 850-867.
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