变频驱动系统电网接口虚拟同步发电机

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摘要网侧功率变换器是变频驱动系统接入配电网的重要接口,随着变频驱动系统渗透率的不断提高,网侧功率变换器对配电网中的影响越发突出。借鉴传统电力系统中的同步发电机数学模型,形成电网接口虚拟同步发电机控制方案,设计具有变频驱动系统自身特性的虚拟调速器和虚拟励磁控制器,保证电网电流的低谐波畸变的同时,满足负荷功率需求,并具有响应电网电压/频率异常事件功能,可在一定程度上提高电网的稳定性。同时模拟同步发电机的转动惯量,提高电网接口的惯性和阻尼,降低变频驱动系统对电网的影响,提升电网对大规模变频驱动系统接入的适应性。为实现电网接口的柔性起动,提出一种虚拟同步预并网控制方法,可实现电网接口柔性离/并网切换,消除起动冲击电流。仿真和实验结果表明了所提控制方案的有效性。

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	吴轩钦
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关键词 ：变频驱动, 电网接口, 虚拟同步发电机, 柔性启动

Abstract：The grid-side power converter is an import interface to access the distribution network for variable frequency drive systems.With the increasing penetration of variable frequency drive systems,the impact of the grid-side power converter on the distribution network becomes much more important.Firstly the virtual synchronous generator control scheme is formed in accordance with the synchronous generator model of traditional power systems,while the virtual speed controller and the virtual excitation controller are designed with the characteristics of variable frequency drive systems,which ensures low harmonic distortion of grid current as well as meets the load’s power need.The system can also respond to the abnormal grid voltage/frequency,which can improve the stability of the grid to a certain degree.Meanwhile,simulating the moment inertia of the synchronous generator can improve the inertia and damping of the grid interface and reduce the impact of variable frequency drive systems on the grid,and thus enhance the adaptability of the grid during the large-scale variable frequency drive system access.To achieve the flexible start of the grid interface,a virtual synchronization pre-connection control method is proposed,which can realize the flexible on/off switching of the grid and eliminate the inrush current.The simulation and experimental results show the effectiveness of the proposed control scheme.

Key words： Variable frequency drive grid interface virtual synchronous generator flexible start

收稿日期: 2015-01-02 出版日期: 2015-12-18

PACS:

TM464

通讯作者: 谭国俊男,1962年生,博士,教授,研究方向为大功率交流传动及电力电子变流技术。

作者简介: 吴轩钦男,1983年生,博士,讲师,研究方向为大功率交流传动及电力电子变流技术

引用本文:

吴轩钦, 谭国俊, 何凤有, 李浩. 变频驱动系统电网接口虚拟同步发电机[J]. 电工技术学报, 2015, 30(23): 83-92. Wu Xuanqin, Tan Guojun, He Fengyou, Li Hao. Virtual Synchronous Generator Control Scheme of Grid Interface for Variable Frequency Drive Systems. Transactions of China Electrotechnical Society, 2015, 30(23): 83-92.

链接本文:

https://dgjsxb.ces-transaction.com/CN/Y2015/V30/I23/83

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