Design and Control of DVR Based on Adaptive Bateman Polynomial for Power Quality Improvement

IF 1.8 3区 工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC
Kanchan Bala Rai, Narendra Kumar, Alka Singh
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Abstract

Power quality issues encompass a spectrum of disturbances that affect the stability and reliability of the power supply. This study explores voltage‐related anomalies, including sags, surges, flickers, unbalances, harmonics, interruptions, and swells, examining their origins, characteristics, and repercussions. These issues arise from a myriad of sources, such as load fluctuations, equipment malfunctions, and grid dynamics. The ramifications of these disturbances extend to equipment malfunctions, reduced operational efficiency, and financial losses. Dynamic voltage restorer (DVRs) are series custom power devices for mitigating these voltage‐related anomalies and use real‐time monitoring and control to quickly inject exact voltages into the grid during disruptions, restoring voltage levels to acceptable levels. This study demonstrates the capacity of DVRs to successfully alleviate power quality concerns, hence improving equipment dependability and system stability by analyzing case studies and simulation findings. The control system used to supply switching signals to the voltage source converter (VSC) of the DVR is based on adaptive Bateman polynomial (ABMP). Traditional DVR control techniques often rely on fixed or linear control strategies, which may not adequately handle varying load conditions and disturbances. ABMP offers an adaptive approach where the control parameters can adjust dynamically based on real‐time system conditions. This adaptive capability enhances the accuracy of voltage restoration, ensuring that the DVR responds optimally to varying loads and disturbances. During voltage sag and swell conditions at the grid side, the VSC injects the compensating voltage in series with the feeder with a constant switching frequency. A battery energy‐supported system (BESS) based DVR is considered for the proposed system. The supply is connected to the critical and sensitive loads. The proposed control scheme is validated through extensive simulation and experimental results.
基于自适应贝特曼多项式的 DVR 设计与控制以改善电能质量
电能质量问题包括一系列影响供电稳定性和可靠性的干扰。本研究探讨了与电压相关的异常现象,包括电压骤降、浪涌、闪烁、不平衡、谐波、中断和胀大,研究了它们的起源、特征和影响。这些问题的来源多种多样,如负荷波动、设备故障和电网动态。这些干扰的后果包括设备故障、运行效率降低和经济损失。动态电压恢复器 (DVR) 是系列定制电力设备,用于缓解这些与电压相关的异常现象,并利用实时监测和控制,在中断期间快速向电网注入精确电压,将电压水平恢复到可接受的水平。本研究通过分析案例研究和仿真结果,展示了 DVR 成功缓解电能质量问题的能力,从而提高设备的可靠性和系统稳定性。用于向 DVR 的电压源转换器 (VSC) 提供开关信号的控制系统基于自适应贝特曼多项式 (ABMP)。传统的 DVR 控制技术通常依赖于固定或线性控制策略,这些策略可能无法充分应对不断变化的负载条件和干扰。ABMP 提供了一种自适应方法,可根据实时系统条件动态调整控制参数。这种自适应能力提高了电压恢复的准确性,确保 DVR 对不同的负载和干扰做出最佳响应。在电网侧出现电压下陷和电压膨胀时,VSC 以恒定的开关频率向馈线串联注入补偿电压。拟议系统考虑采用基于电池能量支持系统(BESS)的 DVR。该电源与关键和敏感负载相连。通过大量的仿真和实验结果验证了所提出的控制方案。
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来源期刊
International Journal of Circuit Theory and Applications
International Journal of Circuit Theory and Applications 工程技术-工程:电子与电气
CiteScore
3.60
自引率
34.80%
发文量
277
审稿时长
4.5 months
期刊介绍: The scope of the Journal comprises all aspects of the theory and design of analog and digital circuits together with the application of the ideas and techniques of circuit theory in other fields of science and engineering. Examples of the areas covered include: Fundamental Circuit Theory together with its mathematical and computational aspects; Circuit modeling of devices; Synthesis and design of filters and active circuits; Neural networks; Nonlinear and chaotic circuits; Signal processing and VLSI; Distributed, switched and digital circuits; Power electronics; Solid state devices. Contributions to CAD and simulation are welcome.
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