An Active Damping Control Strategy for a Multi-Cell AC-DC Solid State Transformer

2020 IEEE Energy Conversion Congress and Exposition (ECCE) Pub Date : 2020-10-11 DOI:10.1109/ECCE44975.2020.9235759

V. Iyer, Srinivas Gulur, S. Bhattacharya

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引用次数: 3

Abstract

Cascaded system stability plays a critical role in the proper operation of any multi-stage power electronic based solid state transformer (SST). Hence, it is imperative to develop small-signal models for the SST system, evaluate its stability margins and develop control based solutions for unstable operating conditions to ensure reliable operation. In this respect, the present work elucidates a system level control strategy for a multi-cell AC-DC SST that can be used to interface with a medium voltage (MV) grid. An active damping control strategy based on classical feedback theory is proposed to improve the stability margins of the individual DC link voltages within the multi-cell SST. This is achieved by emulating a virtual resistance at the individual DC links by employing an active damping control strategy. Such a control strategy presents several attractive benefits such as simple control implementation and does not require additional current or voltage sensors. It is demonstrated through extensive circuit simulations that a single active damping controller can stabilize all the individual DC link voltages within the multi-cell SST leading to excellent performance of the SST system.

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多单元交直流固态变压器的主动阻尼控制策略

级联系统的稳定性对多级电力电子固态变压器的正常运行起着至关重要的作用。因此，必须为SST系统开发小信号模型，评估其稳定裕度，并针对不稳定的运行条件开发基于控制的解决方案，以确保可靠运行。在这方面，目前的工作阐明了可用于与中压(MV)电网接口的多单元交直流SST的系统级控制策略。提出了一种基于经典反馈理论的主动阻尼控制策略，以提高多单元海表温度中单个直流链路电压的稳定裕度。这是通过采用主动阻尼控制策略在单个直流链路上模拟虚拟电阻来实现的。这种控制策略具有简单的控制实现和不需要额外的电流或电压传感器等优点。通过大量的电路仿真证明，单个主动阻尼控制器可以稳定多单元SST内所有单个直流链路电压，从而使SST系统具有优异的性能。

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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2020 IEEE Energy Conversion Congress and Exposition (ECCE)

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