A Dual-Layer Optimal Operation of Multi-Energy Complementary System Considering the Minimum Inertia Constraint

Houjian Zhan, Yiming Qin, Xiaoping Xiong (), Huanxing Qi, Jiaqiu Hu, Jian Tang and Xiaokun Han
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Houjian Zhan: Power Dispatch and Control Center Guangxi Power Grid Co., Ltd., Nanning 530013, China
Yiming Qin: Power Dispatch and Control Center Guangxi Power Grid Co., Ltd., Nanning 530013, China
Xiaoping Xiong: School of Electrical Engineering, Guangxi University, Nanning 530004, China
Huanxing Qi: Power Dispatch and Control Center Guangxi Power Grid Co., Ltd., Nanning 530013, China
Jiaqiu Hu: Power Dispatch and Control Center Guangxi Power Grid Co., Ltd., Nanning 530013, China
Jian Tang: Power Dispatch and Control Center Guangxi Power Grid Co., Ltd., Nanning 530013, China
Xiaokun Han: State Grid Henan Electric Power Company, Zhoukou 466000, China

Energies, 2025, vol. 18, issue 19, 1-25

Abstract: The large-scale utilization of wind and solar energy is crucial for achieving carbon neutrality targets. However, as extensive wind and solar power generation is integrated via power electronic devices, the inertia level of power systems continues to decline. This leads to a significant reduction in the system’s frequency regulation capability, posing a serious threat to frequency stability. Optimizing the system is an essential measure to ensure its safe and stable operation. Traditional optimization approaches, which separately optimize transmission and distribution systems, may fail to adequately account for the variability and uncertainty of renewable energy sources, as well as the impact of inertia changes on system stability. Therefore, this paper proposes a two-layer optimization method aimed at simultaneously optimizing the operation of transmission and distribution systems while satisfying minimum inertia constraints. The upper-layer model comprehensively optimizes the operational costs of wind, solar, and thermal power systems under the minimum inertia requirement constraint. It considers the operational costs of energy storage, virtual inertia costs, and renewable energy curtailment costs to determine the total thermal power generation, energy storage charge/discharge power, and the proportion of renewable energy grid connection. The lower-layer model optimizes the spatiotemporal distribution of energy storage units within the distribution network, aiming to minimize total network losses and further reduce system operational costs. Through simulation analysis and computational verification using typical daily scenarios, this model enhances the disturbance resilience of the transmission network layer while reducing power losses in the distribution network layer. Building upon this optimization strategy, the model employs multi-scenario stochastic optimization to simulate the variability of wind, solar, and load, addressing uncertainties and correlations within the system. Case studies demonstrate that the proposed model not only effectively increases the integration rate of new energy sources but also enables timely responses to real-time system demands and fluctuations.

Keywords: time-varying correlation; minimum inertia; multi-energy complementary; dual-layer optimization; uncertainty (search for similar items in EconPapers)
JEL-codes: Q Q0 Q4 Q40 Q41 Q42 Q43 Q47 Q48 Q49 (search for similar items in EconPapers)
Date: 2025
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