Zhaorui Yang, Yu He, Jing Zhang, Zijian Zhang, Jie Luo, Guomin Gan, Jie Xiang, Yang Zou
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引用次数: 0
Abstract
The integration of large-scale wind power into power systems has exacerbated the challenges associated with peak load regulation. Concurrently, the ongoing advancement of electricity marketization reforms highlights the need to assess the impact of direct electricity procurement by large consumers on enhancing the flexibility of power systems. In this context, this paper introduces a Distributed Robust Optimal Scheduling (DROS) model, which addresses the uncertainties of wind power generation and direct electricity purchases by large consumers. Firstly, to mitigate the effects of wind power uncertainty on the power system, a first-order Markov chain model with interval characteristics is introduced. This approach effectively captures the temporal and variability aspects of wind power prediction errors. Secondly, building upon the day-ahead scenarios generated by the Markov chain, the model then formulates a data-driven optimization framework that spans from day-ahead to intra-day scheduling. In the day-ahead phase, the model leverages the price elasticity of the demand matrix to guide consumer behavior, with the primary objective of maximizing the total revenue of the wind farm. A robust scheduling strategy is developed, yielding an hourly scheduling plan for the day-ahead phase. This plan dynamically adjusts tariffs in the intra-day phase based on deviations in wind power output, thereby encouraging flexible user responses to the inherent uncertainty in wind power generation. Ultimately, the efficacy of the proposed DROS method is validated through extensive numerical simulations, demonstrating its potential to enhance the robustness and flexibility of power systems in the presence of significant wind power integration and market-driven direct electricity purchases.
大规模风力发电融入电力系统加剧了与高峰负荷调节相关的挑战。与此同时,电力市场化改革的不断推进凸显了评估大用户直接购电对提高电力系统灵活性的影响的必要性。在此背景下,本文引入了分布式鲁棒优化调度(DROS)模型,以解决风力发电和大用户直购电的不确定性问题。首先,为了减轻风力发电不确定性对电力系统的影响,本文引入了一个具有区间特性的一阶马尔可夫链模型。这种方法能有效捕捉风电预测误差的时间性和可变性。其次,在马尔科夫链生成的日前情景基础上,该模型制定了一个数据驱动的优化框架,从日前到日内调度。在日前阶段,模型利用需求矩阵的价格弹性来指导消费者行为,主要目标是实现风电场总收入的最大化。我们开发了一种稳健的调度策略,为日前阶段制定了一个小时调度计划。该计划可根据风电输出的偏差动态调整日内阶段的电价,从而鼓励用户灵活应对风力发电中固有的不确定性。最终,通过大量的数值模拟验证了所提出的 DROS 方法的有效性,证明了该方法在大量风电并网和市场驱动的直接购电情况下增强电力系统稳健性和灵活性的潜力。
ElectronicsComputer Science-Computer Networks and Communications
CiteScore
1.10
自引率
10.30%
发文量
3515
审稿时长
16.71 days
期刊介绍:
Electronics (ISSN 2079-9292; CODEN: ELECGJ) is an international, open access journal on the science of electronics and its applications published quarterly online by MDPI.