采用最优效率策略的区域耦合增强型自去耦全向无线电力传输发射机

IF 7.4 1区 工程技术 Q1 AUTOMATION & CONTROL SYSTEMS IEEE Transactions on Industrial Electronics Pub Date : 2024-11-20 DOI:10.1109/TIE.2024.3488361
Musong Li;Xian Zhang;Zhongyu Dai;Zhixin Chen;Ran Wang;Yitong Zhou
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引用次数: 0

摘要

全向无线电力传输(OWPT)系统广泛应用于消费电子产品(cep)、工业机器人、无人检测设备等领域。然而,无方向性电磁能量传递降低了系统的传输效率,增加了自由工作空间的磁场泄漏。此外,现有的控制策略难以同时保证系统的简单性和效率,从而增加了系统的开发和运行成本。本文首次提出了一种高效率、低漏磁的新型发射机结构,它由三个正交放置的方形线圈组成。此外,自解耦重构方法可以进一步激发发射机的潜力,并通过所提出的最优效率策略实现空间电磁场的均匀化。搭建了一个100v / 100khz的OWPT平台,验证了所设计发射机结构的有效性。实验结果表明,在90°旋转范围内,系统效率保持在75.06% ~ 77.17%,波动率最大降低到7.81%。在平面范围内效率提高到86.8%,波动率仅为4.1%。
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Regional Coupling Enhanced Self-Decoupling Omnidirectional Wireless Power Transfer Transmitter With Optimal Efficiency Strategy
Omnidirectional wireless power transfer (OWPT) systems are widely used in consumer electronics products (CEPs), industrial robots, unmanned detection equipment, etc. However, nondirectional electromagnetic energy transfer reduces system transmission efficiency and increases magnetic field leakage in the free working space. Besides, existing control strategies find it difficult to simultaneously ensure system simplicity and efficiency, thereby increasing system development and operating costs. In this article, a novel transmitter structure with high efficiency and low-leakage flux has first proposed, consisting of three square coils placed in an orthogonal position. Moreover, a self-decoupling reconfiguration method can further stimulate the potential of the transmitter, and the space electromagnetic field can be homogenized by the proposed optimal efficiency strategy. An OWPT platform with 100 V/100 kHz is built to prove the effectiveness of our designed transmitter structure. The experiment results show that the system efficiency remains 75.06%–77.17% within a 90° rotation range, with the fluctuation rate reduced to a maximum of 7.81%. The efficiency in the planar range is increased to 86.8%, with a fluctuation rate of only 4.1%.
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来源期刊
IEEE Transactions on Industrial Electronics
IEEE Transactions on Industrial Electronics 工程技术-工程:电子与电气
CiteScore
16.80
自引率
9.10%
发文量
1396
审稿时长
6.3 months
期刊介绍: Journal Name: IEEE Transactions on Industrial Electronics Publication Frequency: Monthly Scope: The scope of IEEE Transactions on Industrial Electronics encompasses the following areas: Applications of electronics, controls, and communications in industrial and manufacturing systems and processes. Power electronics and drive control techniques. System control and signal processing. Fault detection and diagnosis. Power systems. Instrumentation, measurement, and testing. Modeling and simulation. Motion control. Robotics. Sensors and actuators. Implementation of neural networks, fuzzy logic, and artificial intelligence in industrial systems. Factory automation. Communication and computer networks.
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