Coordinated Optimal Dispatch of Distribution Grids and P2P Energy Trading Markets

Coordinated Optimal Dispatch of Distribution Grids and P2P Energy Trading Markets

ABSTRACT With the increasing integration of distributed renewable energy, traditional power users are evolving into prosumers capable of both generation and consumption. However, their decentralized nature poses challenges in resource coordination. This study proposes a bi‐level optimization framewo...

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Bibliographic Details
Main Authors: Jing Deng, Fawu He, Qingbin Zeng, Jie Yan, Rangxiong Liu, Dongsheng He, Song Zhou
Format: Article
Language:English
Published: Wiley 2025-05-01
Series:Energy Science & Engineering
Subjects:
bi‐level optimization
deep reinforcement learning
distribution system operator
peer‐to‐peer (P2P) energy trading
prosumers
shared energy storage
Online Access:https://doi.org/10.1002/ese3.70046
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Summary:ABSTRACT With the increasing integration of distributed renewable energy, traditional power users are evolving into prosumers capable of both generation and consumption. However, their decentralized nature poses challenges in resource coordination. This study proposes a bi‐level optimization framework for distribution networks integrating peer‐to‐peer (P2P) energy trading and shared energy storage. The upper‐level model minimizes distribution system operator (DSO) operational costs, including network losses and storage management, while ensuring voltage stability. The lower‐level model enables prosumers to maximize P2P market profits through adaptive load adjustments and shared storage utilization. To address the nonlinear, high‐dimensional optimization challenges, an improved Convex‐Soft Actor‐Critic (C‐SAC) algorithm is developed, combining deep reinforcement learning with convex optimization to achieve privacy‐preserving distributed coordination. Case studies on an IEEE 33‐node system demonstrate that the framework increases prosumer profits by 56.9%, reduces DSO costs by 23.6%, and lowers network losses by 21.5% compared to non‐cooperative scenarios. The shared storage system reduces capacity and power requirements by 20% and 14.1%, respectively. The C‐SAC algorithm outperforms traditional methods (DDPG, SAC) in convergence speed and economic metrics, showing scalability across larger systems (IEEE 69/118 nodes). This work provides a model‐free solution for renewable‐rich distribution networks, balancing efficiency and operational security.
ISSN:2050-0505

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