Closed-Loop Control of Inductive WPT System Through Variable Inductor

IF 5 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE open journal of power electronics Pub Date : 2024-08-26 DOI:10.1109/OJPEL.2024.3450202

Fabio Corti;Francisco Javier Lopez-Alcolea;Luigi Solimene;Alberto Reatti;Salvatore Musumeci;Pedro Roncero-Sanchez;Alicia Triviño Cabrera

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Abstract

This paper introduces a novel control approach for an LCC-S Wireless Power Transfer (WPT) system. The system's output voltage regulation is achieved through a variable inductor, leveraging magnetic core saturation. A comprehensive design methodology for the variable inductor tailored to the desired control characteristics is presented. Addressing a significant gap in the current literature, the paper addresses the non-trivial challenge of developing a small signal model that correlates output voltage variations with changes in inductance. To fill this gap, the proposed approach pioneers a transfer function, providing an accurate description of this dynamic. Additionally, a closed-loop control system is proposed for prompt adjustment of the output voltage. The efficacy of this control system is demonstrated even in the face of rapid load variations or misalignment, ensuring reliable regulation. The robustness and effectiveness of the proposed approach are substantiated through extensive experimental measurements, validating the theoretical and simulation results.

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通过可变电感器对感应式 WPT 系统进行闭环控制

本文为 LCC-S 无线电力传输（WPT）系统介绍了一种新颖的控制方法。该系统的输出电压调节是通过可变电感器利用磁芯饱和来实现的。本文介绍了针对所需控制特性的可变电感器综合设计方法。针对目前文献中存在的一个重大空白，论文提出了一个非同小可的挑战，即开发一个小信号模型，将输出电压变化与电感变化联系起来。为了填补这一空白，所提出的方法率先采用了传递函数，对这一动态进行了精确描述。此外，还提出了一个闭环控制系统，用于及时调整输出电压。即使在负载快速变化或失调的情况下，该控制系统的功效也得到了验证，从而确保了可靠的调节。通过大量的实验测量，验证了理论和模拟结果，证明了所提方法的稳健性和有效性。

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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