Impacts of Linear Controllers for Power Interfaces in Damping Impedance Model Based Power Hardware-in-the-Loop

2019 IEEE International Conference on Industrial Technology (ICIT) Pub Date : 2019-02-01 DOI:10.1109/ICIT.2019.8755008

N. Marks, W. Kong, Daniel S. Birt

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引用次数: 1

Abstract

Power hardware-in-the-loop (PHIL) is an attractive real-time test and validation technique for large power systems. It can be used instead of full simulation or experimental systems to reduce cost and risk, and improve testing flexibility. A key challenge is achieving a power interface with as much transparency as possible via interface algorithms, power amplifiers, and measurement and control strategies. Voltage source converters (VSCs) are a suitable amplifier option for high power applications due to their relative efficiency, but they restrict the bandwidth and update speed of the power signal reproduced for the Item-under-Test (IuT). The stability and accuracy of the PHIL system are consequently affected by these additional dynamics. This paper evaluates the stability and accuracy of a Damping Impedance Model (DIM) based PHIL system where a VSC power interface is controlled by a linear voltage controller. It will be shown that the stability and accuracy can be improved with the use of a controller, when compared to the simple open loop modulation strategy often used in PHIL applications.

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基于阻尼阻抗模型的电源在环硬件中线性控制器对电源接口的影响

电力硬件在环(PHIL)技术是一种有吸引力的大型电力系统实时测试和验证技术。它可以代替全仿真或实验系统，以降低成本和风险，并提高测试的灵活性。一个关键的挑战是通过接口算法、功率放大器以及测量和控制策略实现尽可能透明的电源接口。电压源转换器(VSCs)由于其相对效率而成为高功率应用的合适放大器选择，但它们限制了被测物(IuT)再现功率信号的带宽和更新速度。因此，这些额外的动态影响了PHIL系统的稳定性和精度。本文评价了基于阻尼阻抗模型(DIM)的PHIL系统的稳定性和精度，其中VSC电源接口由线性电压控制器控制。与PHIL应用中常用的简单开环调制策略相比，使用控制器可以提高稳定性和精度。

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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2019 IEEE International Conference on Industrial Technology (ICIT)

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