基于深度学习的需求响应,促进基于可再生能源的微电网的短期运行

Sina Samadi Gharehveran, Kimia Shirini, Selma Cheshmeh Khavar, Seyyed Hadi Mousavi, Arya Abdolahi
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引用次数: 0

摘要

本文介绍了一种基于深度学习的前沿模型,旨在通过同时最大限度地降低分布式能源资源的运营成本和排放,提高微电网的短期性能。本研究的主要重点是利用需求响应计划 (DRP) 的潜力,该计划积极吸引各类消费者参与,以缓解与可再生能源 (RES) 相关的不确定性。为了促进有效的需求响应,本研究提出了一种新颖的基于激励的支付策略,并将其包装为定价提议。这种方法可以激励消费者积极参与 DRP,从而促进微电网的整体优化。研究通过评估整合和不整合 DRP 的情况下的运营成本和排放,进行了全面的比较分析。该问题被表述为一个具有挑战性的混合整数非线性编程问题,需要一种稳健的优化技术来解决。为此,采用了多目标粒子群优化算法来有效解决这一复杂问题。为了展示所提方法的有效性和熟练性,我们选择了一个真实世界的智能微电网案例研究作为代表。研究结果表明,将基于深度学习的需求响应与基于激励的定价方案相结合,可以显著提高微电网的性能,从而凸显其在现代电力系统中实现可持续、经济高效的能源管理的潜力。关键的数值结果证明了我们方法的有效性。在案例研究中,与未集成需求响应的基线方案相比,实施我们的需求响应策略后,成本降低了 12.5%,碳排放量减少了 14.3%。此外,优化模型显示可再生能源利用率显著提高了 22.7%,从而大大降低了对化石燃料发电的依赖。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Deep learning-based demand response for short-term operation of renewable-based microgrids

Deep learning-based demand response for short-term operation of renewable-based microgrids

This paper introduces a cutting-edge deep learning-based model aimed at enhancing the short-term performance of microgrids by simultaneously minimizing operational costs and emissions in the presence of distributed energy resources. The primary focus of this research is to harness the potential of demand response programs (DRPs), which actively engage a diverse range of consumers to mitigate uncertainties associated with renewable energy sources (RES). To facilitate an effective demand response, this study presents a novel incentive-based payment strategy packaged as a pricing offer. This approach incentivizes consumers to actively participate in DRPs, thereby contributing to overall microgrid optimization. The research conducts a comprehensive comparative analysis by evaluating the operational costs and emissions under scenarios with and without the integration of DRPs. The problem is formulated as a challenging mixed-integer nonlinear programming problem, demanding a robust optimization technique for resolution. In this regard, the multi-objective particle swarm optimization algorithm is employed to efficiently address this intricate problem. To showcase the efficacy and proficiency of the proposed methodology, a real-world smart microgrid case study is chosen as a representative example. The obtained results demonstrate that the integration of deep learning-based demand response with the incentive-based pricing offer leads to significant improvements in microgrid performance, emphasizing its potential to revolutionize sustainable and cost-effective energy management in modern power systems. Key numerical results demonstrate the efficacy of our approach. In the case study, the implementation of our demand response strategy results in a cost reduction of 12.5% and a decrease in carbon emissions of 14.3% compared to baseline scenarios without DR integration. Furthermore, the optimization model shows a notable increase in RES utilization by 22.7%, which significantly reduces reliance on fossil fuel-based generation.

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