风电机组大功率中压功率转换系统的设计方法

S. Mohan, R. Naik
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引用次数: 7

摘要

本文对海上风电系统中典型的中压(3.3kV ~ 4.16kV)大功率(6 ~ 10mw)多级变流器功率转换阶段的设计方法进行了研究和评价。海上风力发电机的背靠背交-直流-交多级功率转换级通常由一台额定功率为6-10MW的永磁同步发电机(PMSG)驱动。该设计方法主要依靠开发的综合仿真模型,旨在建立在中压功率半导体器件的热极限约束下,功率转换阶段的功率处理能力,交付给电网的电能质量(对于电网功率因数要求为0.9到1)和整体效率。基于已开发的线侧和发电机侧转换器的控制,半导体器件的瞬时损耗模型允许基于器件的热模型估计瞬时结温。虽然本文提供了不同的中压功率半导体器件的概述,但所提供的分析主要集中在集成门换向晶闸管(IGCT)上。然后根据热约束确定6-10MW功率水平下可实现的最大开关频率。然后,为确定的开关频率适当选择滤波器元件,可以量化功率转换阶段的功率质量和整体系统效率。最后确定了线侧和发电机侧变流器在不同功率水平下可实现的开关频率,以及在不同工作点下可实现的电能质量和效率。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Design approach for high power, medium voltage power conversion systems for wind turbines
In this paper, the design approach for the power conversion stage of typical medium voltage (3.3kV to 4.16kV), high power (6-10MW) multi-level converters like those used in offshore wind turbine systems is investigated and evaluated. The back-to-back AC-DC-AC multi-level power conversion stage for offshore wind turbines is usually driven by a Permanent Magnet Synchronous Generator (PMSG) for power ratings of the order of 6-10MW. The design approach, primarily relying on a comprehensive simulation model developed, aims to establish the power processing capability of the power conversion stage under the constraints of the thermal limits of the medium voltage power semiconductor devices, the power quality delivered to the grid (for power factor requirements of 0.9 to unity at the grid) and the overall efficiency. Based on the developed controls for the line-side and the generator-side converter, an instantaneous loss model of the semiconductor devices allows estimation of the instantaneous junction temperatures based on thermal models for the devices. Although the paper provides an overview of the different medium voltage power semiconductor devices, the analysis provided focusses primarily on the Integrated Gate Commutated Thyristor (IGCT). The maximum switching frequencies achievable at the power levels of 6-10MW is then determined based on the thermal constraints. Appropriate selection of the filter elements for the determined switching frequencies then enables quantification of the power quality and the overall system efficiency of the power conversion stage. The achievable switching frequencies at the different power levels of the line-side and the generator-side converters is finally established, along with the achievable power quality and efficiencies at the different operating points.
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