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基于动态运行场景预测的多能微电网实时能量优化调控方法OA

A Real-Time Energy Optimal Dispatch Method for Multi-Energy Microgrids Based on Dynamic Operation Scenario Forecasting

中文摘要英文摘要

多能微电网(MEMG)在推动能源效率提升与促进可再生分布式发电(RDG)消纳等方面展现出了巨大潜力,但其运行面临源于 RDG 和多能负荷的多维不确定性所引发的挑战.为此,该文提出了一种基于动态运行场景预测的 MEMG 实时能量优化调控方法.该方法针对 MEMG运行场景构建了瓦瑟斯坦生成对抗网络,以无监督方式挖掘与表征其统计分布,并基于此创建了场景预测约束优化问题,实现了可捕捉多维不确定性的 MEMG 运行场景的高效、高质量以及逐时刻预测.基于预测场景形成了随机模型预测控制框架下的 MEMG 预调度模型,并构建了实时功率补偿模型以最为经济的方式对电热不平衡功率进行补偿.最后,通过数值仿真验证了所提MEMG 运行场景预测和能量调控方法的有效性.

The multi-energy microgrid(MEMG)has a high degree of integration among various types of energy systems during the planning,construction and operation process,realizing synergistic planning and coordinated operation among multiple heterogeneous energy forms of production,consumption and storage units.Through the complementarity among various forms of energy,MEMG shows great potential in enhancing the comprehensive utilization efficiency of energy,reducing the cost of energy usage and promoting the accommodation of renewable distributed generation(RDG),which is of great significance in promoting energy transition and realizing sustainable development.However,the multi-dimensional uncertainties induced by the dynamic changes in multi-energy loads and the intermittent and stochastic nature of RDG pose great challenges to the optimal dispatch and reliable operation of MEMG,which need to be urgently addressed in the process of MEMG energy dispatch.To this end,a real-time energy optimal dispatch method for MEMG based on dynamic operation scenario forecasting was proposed in this paper.The method characterizes MEMG operation uncertainties by dynamically forecasting a set of operation scenarios at each time slot,thus effectively addressing the negative impact of multi-dimensional uncertainties on MEMG operation. Firstly,a Wasserstein generative adversarial network(WGAN)suitable for the characteristics of MEMG operation scenarios was constructed in the method to mine and characterize their intrinsic statistical distribution in an unsupervised manner.Secondly,a constrained optimization problem for scenario forecasting was formulated based on known information(observations and point predictions of uncertain variables)and combined with the well-trained WGAN.It achieves efficient,high-quality and time-to-time forecasting of MEMG operation scenarios by optimizing the input vectors of the generator to effectively capture the multi-dimensional uncertainties of MEMG for a coming period.Finally,a MEMG pre-scheduling model was developed in the stochastic model predictive control framework based on the forecasted scenarios to accurately obtain the MEMG pre-scheduling commands.A real-time power compensation model was also constructed to compensate for the unbalanced electric and thermal power in the most economical manner,thereby ensuring the real-time power balance of MEMG. Comprehensive numerical simulations fully validate the effectiveness of the proposed MEMG operation scenario forecasting and real-time energy optimal dispatch method.The developed scenario forecasting method can effectively forecast the MEMG operation scenarios in different forecast time ranges and can effectively capture the edge distribution of the actual scenarios,realizing the accurate characterization of the uncertainties for MEMG operation in a coming period.Meanwhile,the real-time energy optimal dispatch method constructed based on the forecasted scenarios effectively mitigates the negative impact of multi-dimensional uncertainties on MEMG operation,and shows more significant economic benefits than the traditional model predictive control method. In the future,the energy forms integrated into MEMG will be more diversified,the forms of MEMG will be more complex and diverse,and their control will be more intelligent.Therefore,future research will focus on how to use digital twins and other advanced tools to improve the operation state sensing level and fine dispatch performance of MEMG with close coupling among energy forms such as hydrogen,biomass,heat,gas,electricity,etc.

王玉彬;杨强;夏明超;陈奇芳;孙谦浩

北京交通大学电气工程学院 北京 100044浙江大学电气工程学院 杭州 310027北京交通大学电气工程学院 北京 100044北京交通大学电气工程学院 北京 100044北京交通大学电气工程学院 北京 100044

信息技术与安全科学

多能微电网可再生分布式发电多维不确定性生成对抗网络场景预测随机模型预测控制

Multi-energy microgridrenewable distributed generationmulti-dimensional uncertaintiesgenerative adversarial networkscenario forecastingstochastic model predictive control

《电工技术学报》 2026 (7)

2237-2252,16

国家自然科学基金资助项目(52337003,52177119).

10.19595/j.cnki.1000-6753.tces.250575

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