Design and Performance Analysis of Synchronization techniques under Non-Ideal conditions

2019 International Conference on Power Electronics, Control and Automation (ICPECA) Pub Date : 2019-11-01 DOI:10.1109/ICPECA47973.2019.8975390

Ankit Singhal, Alka Singh

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Abstract

This paper discusses the design and performance aspects of synchronization techniques. First, the symmetrical optimum is a method to design a PI regulator gains, which is used in conventional SRF-PLL. This PLL is an extensively used synchronization method to connect a grid side power converter to the grid. Under ordinary grid circumstances, high-bandwidth of PI-regulator gains in SRF-PLL provide a quick and accurate detection of grid voltage amplitude and phase angle. However, under non-ideal conditions, the phase angle could be tracked but with less accuracy. How to further enhance their dynamic output during non-ideal grid situation is a significant challenge with the SRF-PLL. This paper discusses a second synchronization method based on a generalized integrator-frequency loop (SOGI-FLL) in second-order to solve this problem. A new SOGI-FDE-FLL consisting of SOGI-FDE and SOGI-FLL is used to quickly detect accurate monitoring of grid voltage, frequency and angle of phase. SOGI-FDE is used to identify a fundamental positive sequence voltage under unbalanced conditions. The effectiveness of the SOGI-FDE-FLL is confirmed through simulation and compared with Type-2 SRF-PLL.

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非理想条件下同步技术的设计与性能分析

本文讨论了同步技术的设计和性能方面的问题。首先，对称优化是一种用于传统SRF-PLL的PI稳压器增益设计方法。这种锁相环是一种广泛使用的同步方法，将电网侧的电源转换器连接到电网。在普通电网环境下，SRF-PLL的高带宽pi调节器增益提供了快速准确的电网电压幅值和相位角检测。然而，在非理想条件下，可以跟踪相位角，但精度较低。如何在非理想电网情况下进一步提高其动态输出是SRF-PLL面临的一个重大挑战。本文讨论了一种基于二阶广义积分器-频率环的二次同步方法来解决这一问题。由SOGI-FDE和SOGI-FLL组成的新型SOGI-FDE- fll可快速检测准确监测电网电压、频率和相位角。SOGI-FDE用于在不平衡条件下识别基波正序电压。通过仿真验证了SOGI-FDE-FLL的有效性，并与2型SRF-PLL进行了比较。

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 International Conference on Power Electronics, Control and Automation (ICPECA)

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