Modelling and Experimental Evaluation of Ideal Transformer Algorithm Interface for Power Hardware in the Loop Architecture

2020 IEEE Applied Power Electronics Conference and Exposition (APEC) Pub Date : 2020-03-01 DOI:10.1109/APEC39645.2020.9124046

Mandip Pokharel, Carl Ngai Man Ho

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引用次数: 1

Abstract

Interface devices are crucial to achieving Power Hardware in the Loop (PHIL) configuration. It is the interface that separates PHIL implementation with its real counterpart. This inclusion of interface at power decoupling point has raised the concern of stability and accuracy among researchers. It is therefore essential to study the effect of interface if the PHIL system is to be entirely understood. Ideal Transformer Algorithm (ITA) is one of the widely used interfacing method for PHIL due to its implementation simplicity. Moreover, the existing models of ITA relies only on the theoretical model developed. This work constitutes the study and development of accurate mathematical model of individual interface devices in ITA. Further, this paper uses a frequency sweep approach to determine the responses from the actual system consisting of a Real Time Digital Simulator (RTDS). This experimentally obtained frequency response is then compared with model response to test the accuracy of the developed model. This paper therefore bridges the existing gap in interface model by experimentally verifying the developed model. The theoretical and experimental model are well within agreement to further the studies in PHIL.

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电力硬件环路结构理想变压器算法接口的建模与实验评价

接口设备是实现电源硬件在环路(PHIL)配置的关键。正是这个接口将PHIL实现与其真正的对应物区分开来。在功率解耦点加入接口，引起了研究人员对稳定性和准确性的关注。因此，研究界面的影响是完全理解PHIL系统的必要条件。理想变压器算法(ITA)由于其实现简单，是目前广泛使用的PHIL接口方法之一。此外，现有的ITA模型仅依赖于所开发的理论模型。这项工作构成了ITA中单个接口器件精确数学模型的研究和开发。此外，本文使用频率扫描方法来确定由实时数字模拟器(RTDS)组成的实际系统的响应。然后将实验得到的频率响应与模型响应进行比较，以检验所建立模型的准确性。因此，本文通过实验验证所建立的模型，弥补了现有界面模型的不足。理论模型和实验模型都很好地满足了进一步研究的需要。

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 Applied Power Electronics Conference and Exposition (APEC)

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