内嵌数据驱动的三相不平衡有源配电网两阶段动态最优潮流调度方法

doi:10.19595/j.cnki.1000-6753.tces.250556

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Abstract

In the context of energy transition and the construction of new type power systems, distribution networks are gradually evolving into a critical link for supporting the consumption of renewable energy. The large-scale integration of distributed photovoltaic systems and electric vehicles has driven a structural transformation of distribution networks from a unidirectional radial topology to a bidirectional interactive one, leading to technical challenges such as node voltage violations, increased network losses, and three-phase voltage unbalance. Traditional mathematical programming methods face challenges due to their high computational complexity, which makes online decision-making difficult to implement. Meanwhile, deep reinforcement learning algorithms exhibit limitations in managing the regulation of multi-timescale active management devices. There is an urgent need to research operational adjustment strategies tailored to the characteristics of active distribution networks to ensure their safe, stable, and efficient operation.
To address these issues, a “day-ahead and intra-day” two-stage dynamic optimal power flow dispatch method for three-phase unbalanced active distribution networks is proposed, incorporating data-driven approaches. This method leverages the advantages of both physical mechanism modeling and data-driven learning to achieve refined coordinated control of multiple types of regulation resources. Firstly, considering the constraints of active management and demand response, a dynamic optimal power flow model for three-phase unbalanced active distribution networks is established, with the objectives of voltage regulation and loss reduction. Then, at the hour-level long timescale of day-ahead dispatch, the tap positions of slow discrete regulating devices are determined using mixed-integer second-order cone programming with lift-and-project relaxation. At the minute-level short timescale of intra-day dispatch, the dynamic optimal power flow problem is formulated as a Markov decision process, and an improved proximal policy optimization algorithm based on expert knowledge and a hierarchical reward shaping mechanism is proposed for online dispatch of fast continuous regulating devices.
Simulation analyses are conducted using the IEEE 33-bus and 123-bus three-phase radial distribution networks as case studies, drawing the following conclusions: (1) During the day-ahead optimization stage, considering the inter-phase and temporal coupling relationships, the tap positions of slow discrete regulating devices such as capacitor banks and on-load tap-changers are determined by using mixed-integer second-order cone programming with lift-and-project relaxation. Both the fitting error and the relaxation deviation degree of the proposed method are less than 10^-3, indicating an improvement in computational accuracy compared to traditional methods. (2) During the intra-day optimization stage, the dynamic optimal power flow problem is transformed into a Markov decision process, and online control of fast continuous regulating devices such as distributed photovoltaic systems, electric vehicles, energy storage systems, and static var compensators is carried out based on the improved proximal policy optimization algorithm. By comprehensively considering the constraints of active management and demand response, a collaborative optimization of voltage regulation and loss reduction in active distribution networks is achieved, while ensuring that the three-phase voltage unbalance degree meets the national standard limit of 2%. (3) The proposed improved proximal policy optimization algorithm, on one hand, enhances the enforcement capability of the three-phase voltage unbalance degree constraint and effectively guides the agent to reduce active power curtailment of distributed photovoltaic systems by introducing expert knowledge. On the other hand, it adopts a hierarchical reward shaping mechanism that dynamically couples the immediate reward with long-term performance indicators to adapt to the multi-timescale dispatch requirements of the day-ahead and intra-day stages. The algorithm can balance both solution efficiency and accuracy, exhibiting superior computational performance.

Key words： Active distribution network voltage regulation and loss reduction three-phase unbalance two-stage dynamic optimal power flow mixed-integer second-order cone programming improved proximal policy optimization

Received: 08 April 2025

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	Chen Yanbo
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Chen Yanbo,Tian Haoxin,Qiang Tuben等. A Two-Stage Dynamic Optimal Power Flow Dispatch Method for Three-Phase Unbalanced Active Distribution Networks Incorporating Data-Driven Approaches[J]. Transactions of China Electrotechnical Society, 0, (): 20250556-20250556.

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