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Energy Management for Microgrids with Hybrid Hydrogen-Battery Storage: A Reinforcement Learning Framework Integrated Multi-Objective Dynamic Regulation

Yi Zheng, J Jia, Dou An

2025Processes15 citationsDOIOpen Access PDF

Abstract

The integration of renewable energy resources (RES) into microgrids (MGs) poses significant challenges due to the intermittent nature of generation and the increasing complexity of multi-energy scheduling. To enhance operational flexibility and reliability, this paper proposes an intelligent energy management system (EMS) for MGs incorporating a hybrid hydrogen-battery energy storage system (HHB-ESS). The system model jointly considers the complementary characteristics of short-term and long-term storage technologies. Three conflicting objectives are defined: economic cost (EC), system response stability, and battery life loss (BLO). To address the challenges of multi-objective trade-offs and heterogeneous storage coordination, a novel deep-reinforcement-learning (DRL) algorithm, termed MOATD3, is developed based on a dynamic reward adjustment mechanism (DRAM). Simulation results under various operational scenarios demonstrate that the proposed method significantly outperforms baseline methods, achieving a maximum improvement of 31.4% in SRS and a reduction of 46.7% in BLO.

Topics & Concepts

Reinforcement learningBattery (electricity)Energy storageEnergy managementComputer scienceReinforcementEnergy (signal processing)EngineeringPower (physics)Artificial intelligencePhysicsQuantum mechanicsStructural engineeringMicrogrid Control and OptimizationSmart Grid Energy ManagementElectric Vehicles and Infrastructure
Energy Management for Microgrids with Hybrid Hydrogen-Battery Storage: A Reinforcement Learning Framework Integrated Multi-Objective Dynamic Regulation | Litcius