RoCoF Calculation Using Low-Cost Hardware in the Loop: Multi-area Nordic Power System

2020 International Conference on Smart Systems and Technologies (SST) Pub Date : 2020-10-14 DOI:10.1109/SST49455.2020.9264119

J.A. Barrios-Gomez, F. Sanchez, G. Claudio, F. Gonzalez-Longatt, M. Acosta, D. Topić

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引用次数: 3

Abstract

This research paper presents a rate of change of frequency (RoCoF) implementation using low-cost hardware in the loop (HIL) with application to Nordic Power System (NPS). Two methods to calculate the RoCoF are presented: Incremental difference one step and moving window (MW) or rolling window. HIL) approach is used to reach natural noise levels found in the frequency signal obtained from real power devices. The low-cost HIL implementation is based on two Arduinos® in the loop. An Arduino® working as standalone is used to generate an analogue signal representative of one area of the NPS, a second Arduino® in the loop contains the RoCoF calculation methods and filters. This paper analyses the effect of including lowpass filters (LPFs) because the noise of the frequency affects the RoCoF calculation. Three cases are implemented in the Arduino® and compared with Simulink®/MTALAB™ simulations: Base Case: no filter and noise signal, Case I: LPF applied to the input frequency signal, Case II: LPF at the frequency signal and LFP at the output of the RoCoF (smoothing). Results demonstrate that RoCoF calculation methods worked correctly in the HIL and using two LPFs clean the signal from the noise produced by the Arduino®.

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低成本硬件在回路中的RoCoF计算:多区域北欧电力系统

本文提出了一种基于低成本硬件在环(HIL)的频率变化率(RoCoF)实现方法，并应用于北欧电力系统(NPS)。提出了两种计算RoCoF的方法:一步差分增量法和移动窗法或滚动窗法。HIL)方法用于达到从实际功率器件获得的频率信号中发现的自然噪声水平。低成本的HIL实现基于两个Arduinos®在循环中。一个独立工作的Arduino®用于生成代表NPS一个区域的模拟信号，环路中的第二个Arduino®包含RoCoF计算方法和滤波器。本文分析了低频滤波器的影响，因为频率噪声会影响RoCoF的计算。在Arduino®中实现了三种情况，并与Simulink®/MTALAB™仿真进行了比较:基本情况:无滤波器和噪声信号，情况I: LPF应用于输入频率信号，情况II: LPF用于频率信号，LFP用于RoCoF输出(平滑)。结果表明，RoCoF计算方法在HIL中正确工作，并且使用两个lpf从Arduino®产生的噪声中清除信号。

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 International Conference on Smart Systems and Technologies (SST)

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