Affiliation:
1. Higher School of Communication of Tunis (SupCom), University of Carthage, Ariana 2083, Tunisia
2. Chair of Distributed Information Systems, University of Passau, Innstraße 41, 94032 Passau, Germany
Abstract
Vanadium redox-flow batteries (VRFBs) have played a significant role in hybrid energy storage systems (HESSs) over the last few decades owing to their unique characteristics and advantages. Hence, the accurate estimation of the VRFB model holds significant importance in large-scale storage applications, as they are indispensable for incorporating the distinctive features of energy storage systems and control algorithms within embedded energy architectures. In this work, we propose a novel approach that combines model-based and data-driven techniques to predict battery state variables, i.e., the state of charge (SoC), voltage, and current. Our proposal leverages enhanced deep reinforcement learning techniques, specifically deep q-learning (DQN), by combining q-learning with neural networks to optimize the VRFB-specific parameters, ensuring a robust fit between the real and simulated data. Our proposed method outperforms the existing approach in voltage prediction. Subsequently, we enhance the proposed approach by incorporating a second deep RL algorithm—dueling DQN—which is an improvement of DQN, resulting in a 10% improvement in the results, especially in terms of voltage prediction. The proposed approach results in an accurate VFRB model that can be generalized to several types of redox-flow batteries.
Funder
Open Access Publication Fund of the University Library at the University of Passau
German Federal Ministry for Digital and Transport
Subject
Electrical and Electronic Engineering,Electrochemistry,Energy Engineering and Power Technology
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