Control of DFIG Wind Turbines Based on Indirect Matrix Converters in Short Circuit Mode to Improve the LVRT Capability

Advances in Power Electronic Pub Date : 2013-12-12 DOI:10.1155/2013/157431

A. Khajeh, R. Ghazi

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引用次数: 9

Abstract

Nowadays, the doubly-fed induction generators (DFIGs) based wind turbines (WTs) are the dominant type of WTs. Traditionally, the back-to-back converters are used to excite the rotor circuit of DFIG. In this paper, an indirect matrix converter (IMC) is proposed to control the generator. Compared with back-to-back converters, IMCs have numerous advantages such as higher level of robustness, reliability, and reduced size and weight due to the absence of bulky electrolytic capacitor. According to the recent grid codes wind turbines must have low voltage ride-through (LVRT) capability. In this paper a new crowbar system is proposed so that along with the control system it protects the IMC from large fault currents and supports the grid voltage dips during grid faults. This crowbar system is provided using the existing converter switches to establish a short circuit mode without any extra circuitry. Even in severe fault conditions, the duration of short circuit mode is quite small so the control system will be activated shortly after the fault to inject reactive power as required by new LVRT standards. Therefore, the new LVRT standards are well satisfied without any extra costs. PSIM simulation results confirm the efficiency of the proposed method.

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基于间接矩阵变换器的DFIG风电机组短路控制提高LVRT性能

目前，以双馈感应发电机(DFIGs)为基础的风力发电机(WTs)是风力发电机的主要类型。传统上采用背靠背变换器对DFIG的转子电路进行励磁。本文提出了一种间接矩阵变换器(IMC)来控制发电机。与背靠背转换器相比，imc具有许多优点，例如更高水平的稳健性和可靠性，并且由于没有笨重的电解电容器而减小了尺寸和重量。根据最近的电网规范，风力发电机必须具有低电压穿越能力。本文提出了一种新的撬棍系统，该系统与控制系统一起保护IMC免受大故障电流的影响，并在电网故障时支持电网电压下降。该撬棍系统使用现有的转换开关来建立短路模式，而无需任何额外的电路。即使在严重故障条件下，短路模式持续时间也很短，因此控制系统将在故障发生后不久启动，按照新的LVRT标准的要求注入无功功率。因此，新的LVRT标准在没有任何额外成本的情况下很好地满足了要求。PSIM仿真结果验证了该方法的有效性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Advances in Power Electronic

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