一种聚焦无人机着陆方向的水下无线输电电容耦合器设计

IF 0.6 4区工程技术 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC

IEICE Transactions on Electronics Pub Date : 2023-01-01 DOI:10.1587/transele.2023ecp5023

Yasumasa NAKA, Masaya TAMURA

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引用次数: 0

摘要

针对无人机的着陆方向，设计了一种用于水下无线电力传输的电容耦合器。主要的设计特点是功率馈送/接收点在耦合器电极上的相对位置，这取决于无人机的着陆方向。首先，推导了在均匀介质环境下不同馈电位置耦合线的最大功率传输效率，例如在水下实现的传输效率。因此，这些都是由电容耦合器的耦合系数、介质的空载合格系数和具有复传播常数的双曲函数来表示的。双曲函数的变化取决于相对位置，以及这些耦合器是相同的还是相反的，每个耦合器的效率取决于水的类型，如海水和自来水。实验结果表明，该设计方法在自来水传输距离为20、50和100 mm时的效率最高，分别为95.2%、91.5%和85.3%。

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Design of a Capacitive Coupler for Underwater Wireless Power Transfer Focused on the Landing Direction of a Drone

This paper presents the design of a capacitive coupler for underwater wireless power transfer focused on the landing direction of a drone. The main design feature is the relative position of power feeding/receiving points on the coupler electrodes, which depends on the landing direction of the drone. First, the maximum power transfer efficiencies of coupled lines with different feeding positions are derived in a uniform dielectric environment, such as that realized underwater. As a result, these are formulated by the coupling coefficient of the capacitive coupler, the unloaded qualify factor of dielectrics, and hyperbolic functions with complex propagation constants. The hyperbolic functions vary depending on the relative positions and whether these are identical or opposite couplers, and the efficiencies of each coupler depend on the type of water, such as seawater and tap water. The design method was demonstrated and achieved the highest efficiencies of 95.2%, 91.5%, and 85.3% in tap water at transfer distances of 20, 50, and 100 mm, respectively.

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来源期刊

IEICE Transactions on Electronics 工程技术-工程：电子与电气

CiteScore

1.00

自引率

20.00%

发文量

审稿时长

3-6 weeks

期刊介绍： Currently, the IEICE has ten sections nationwide. Each section operates under the leadership of a section chief, four section secretaries and about 20 section councilors. Sections host lecture meetings, seminars and industrial tours, and carry out other activities. Topics: Integrated Circuits, Semiconductor Materials and Devices, Quantum Electronics, Opto-Electronics, Superconductive Electronics, Electronic Displays, Microwave and Millimeter Wave Technologies, Vacuum and Beam Technologies, Recording and Memory Technologies, Electromagnetic Theory.