Stability Analysis and HIL Validation of PV Park Voltage Control Considering Communication Delays

IF 3.9 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE open journal of power electronics Pub Date : 2025-03-08 DOI:10.1109/OJPEL.2025.3568529

Behnam Daftary Besheli;Federico Cecati;Sante Pugliese;Marco Liserre Fellow;Johanna Kristin Maria Becker;Mario Paolone

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Abstract

With advances in industrial data communication technologies, MW-scale PV parks increasingly depend on communication-based coordination among Power Electronic Converters (PECs) to ensure precise voltage regulation and stability, especially during grid fault events. However, Communication Delay (CD) can degrade voltage control, leading to sustained oscillations and Transient Overvoltage (TOV) during post-fault recovery. This paper analyzes the impact of such delays on PV park stability under a centralized secondary voltage controller (SecVC) and proposes a local control strategy to enhance coordination robustness to CDs. A nonlinear model of a PV park is built and used for small-signal stability analysis, incorporating Monte-Carlo Simulations (MCS) to assess the impact of stochastic delays, alongside time-domain simulations to evaluate dynamic responses. The proposed approach is validated through Hardware-in-the-Loop (HIL) testing, using two HIL devices interfaced via a communication network emulator (CNE) with the Modbus-TCP protocol.

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考虑通信延迟的光伏电站电压控制稳定性分析及HIL验证

随着工业数据通信技术的进步，兆瓦级光伏园区越来越依赖于基于通信的电力电子转换器（PECs）之间的协调，以确保精确的电压调节和稳定性，特别是在电网故障事件期间。然而，通信延迟（CD）会降低电压控制，导致故障后恢复过程中的持续振荡和瞬态过电压（TOV）。本文分析了集中式二次电压控制器（SecVC）下这些延迟对光伏电站稳定性的影响，并提出了一种局部控制策略来增强对CDs的协调鲁棒性。建立了光伏电站的非线性模型，并将其用于小信号稳定性分析，结合蒙特卡罗模拟（MCS）来评估随机延迟的影响，以及时域模拟来评估动态响应。通过硬件在环（HIL）测试验证了所提出的方法，使用两个HIL设备通过通信网络模拟器（CNE）与Modbus-TCP协议进行接口。

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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