Capacity Optimization of Hybrid Energy Storage Systems in Microgrid Using Empirical Mode Decomposition and Neural Network

Q1 Engineering 电力系统自动化 Pub Date : 2015-01-01 DOI:10.7500/AEPS20140719002

孙承晨 Sun Chengchen, 袁越 Yuan Yue, S. Choi, 李梦婷 Li Mengting, 张新松 Zhang Xinsong, 曹扬 Cao Yang

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引用次数: 16

Abstract

A new approach to determine the capacity of a supercapacitor-battery hybrid energy storage system(HESS)in an independent microgrid is presented.Using empirical mode decomposition technique,the historical non-stationary wind power is firstly analyzed to yield some intrinsic mode functions(IMFs)of wind power.From the instantaneous frequency-time profiles of the IMF,the so-called gap frequency is identified and allows wind power to be decomposed into high and low frequency components.Power smoothing is then achieved by regulating the output power of the supercapacitor and battery to mitigate the high and lower frequency fluctuating components of power respectively.The degree of smoothness of the resulting power delivered to load is assessed in terms of a newly developed level of smoothness(LOS)criteria.A neural network model is utilized to determine the capacity of the HESS through finding a compromise between the cost of the system and the LOS of the power.Simulation results,based on a set of data obtained from a real wind farm,demonstrate the efficiency of the proposed approach.

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基于经验模态分解和神经网络的微电网混合储能系统容量优化

提出了一种确定独立微电网中超级电容器-电池混合储能系统容量的新方法。首先利用经验模态分解技术对历史非平稳风电进行分析，得到风电的一些固有模态函数。从IMF的瞬时频率-时间剖面中，确定了所谓的间隙频率，并允许将风电分解为高频和低频分量。然后通过调节超级电容器和电池的输出功率来分别减轻功率的高频和低频波动分量，从而实现功率平滑。根据新开发的平滑水平(LOS)标准来评估交付给负载的最终功率的平滑程度。利用神经网络模型，通过寻找系统成本与电力LOS之间的平衡点来确定HESS的容量。基于实际风电场数据的仿真结果验证了该方法的有效性。

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来源期刊

电力系统自动化 Energy-Energy Engineering and Power Technology

CiteScore

8.20

自引率

0.00%

发文量

15032

期刊介绍： Founded in 1977, Power System Automation is a well-known journal in the discipline of electrical engineering in China. At present, it has been issued to all provinces, cities, autonomous regions, Hong Kong, Macao and Taiwan, and abroad to dozens of countries in North America, Europe and Asia-Pacific region, with a large number of readers at home and abroad. Power System Automation takes “based on China, facing the world, seeking truth and innovation, promoting scientific and technological progress in the field of electric power and energy” as the purpose of the journal, mainly for the professional and technical personnel, teachers and students engaged in scientific research, design, operation, testing, manufacturing, management and marketing in the electric power industry and higher education institutions as well as electric power users, and focuses on hotspots of the industry's development and the It focuses on the hot and difficult issues of the industry. It focuses on the hot and difficult issues of the industry, both academic and forward-looking, practical and oriented, and at the same time emphasizes and encourages technical exchanges of experiences, improvements and innovations from the front line of scientific research and production.