A Review on the Recent Development in the Design and Optimization of Magnetic Coupling Mechanism of Wireless Power Transmission

Dai, Zhongyu; Wang, Junhua; Zhou, Haikuo; Huang, Hong

doi:10.1109/jsyst.2020.3004201

Cited by 28 publications

(9 citation statements)

References 124 publications

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“…There is a literature on the design of spiral coil for power transmission, and a three-dimensional magnetic coupling mechanism is designed. However, it is not suitable, complex and inefficient for robot systems [8,9]. Some scholars have analyzed the characteristics of the square coil magnetic coupling mechanism, and compared it with the circular coil using the control variable method.…”

Section: Magnetic Coupler Fig 1 Robot Magnetic Coupling Mechanism Dia...mentioning

confidence: 99%

Design of magnetic coupling mechanism for wireless power transmission system based on magnetic flux analysis

Xiao

Yin

Gong

et al. 2022

J. Phys.: Conf. Ser.

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Aiming at the wireless charging system that can dynamically change arbitrarily in a three-dimensional space such as a smart robot, this paper proposes a new type of magnetic coupling mechanism that combines a disc coil and a spiral coil. It can not only avoid frequency splitting in the short-distance range, but also effectively enhance the coupling strength in the long-distance range. In addition, it can also effectively improve the position robustness and anti-offset ability of the robot’s wireless charging system. In this paper, the geometric framework of the new magnetic coupling mechanism is first given. Based on the analysis of magnetic flux, it is theoretically confirmed that the magnetic coupling mechanism can reduce the coupling strength in the near range, avoid the frequency splitting phenomenon, and improve the coupling strength of the system and the energy efficiency of the system in the long range. Finally, based on the finite element simulation software COMSOL, it is proved that the proposed magnetic coupling mechanism can achieve high energy efficiency output in a large range, and has strong position robustness and anti-deviation.

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Section: Magnetic Coupler Fig 1 Robot Magnetic Coupling Mechanism Dia...mentioning

confidence: 99%

Design of magnetic coupling mechanism for wireless power transmission system based on magnetic flux analysis

Xiao

Yin

Gong

et al. 2022

J. Phys.: Conf. Ser.

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“…In the recent 10 years, as the MCR-WPT was put forward by the MIT, the WPT technology has entered the stage of vigorous development [1]. Considering the power level of WPT devices [19], the WPT system with four categories of micro power level (implantable device, wireless sensor), low power level (portable device), medium power level (drone, robot), and high power level (EV, underwater wireless power supply) are designed.…”

Section: Background Of Metamaterials In Wpt Systemmentioning

confidence: 99%

Development and prospects of metamaterial in wireless power transfer

Huang

Zhang

Cong

et al. 2021

IET Power Electronics

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As a unique group of advanced artificial materials, metamaterials have found many interesting applications in various devices due to the ability to control electromagnetic fields. The metamaterial provides the prospect of new opportunities for the wireless power transfer (WPT) system to improve efficiency and reduce magnetic flux density. This review paper evaluates the performance of the WPT system with metamaterial from both principles and functions aspects. The objectives of this review include: (1) to present the research process and bottlenecks of metamaterial in the WPT system; (2) to clarify the design solution and checking method of the metamaterial and (3) to identify the challenges and opportunities based on the functional of the WPT system integration with metamaterial. Therefore, the process on metamaterial design, working principle of metamaterial, optimal method, equivalent model, and experimental method are reviewed. The recent efforts of the WPT system with metamaterial in efficiency enhancement, misalignments, magnetic field reduction are illustrated. Finally, the challenges and prospects of metamaterial based on the WPT system are concluded.

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“…MI is also employed as a node identifier, similar to Radio Frequency Identification (RFID) functionality [7]. Additionally, there is Omnidirectional-MI capable of transmitting power and data in all directions [8], MI transmitted using metallic materials [9], Multiple-Links (MLs) MI for simultaneous power and data transmission [10], 3-Dimensional coil-engineered MI to enhance energy efficiency [11], and optimization of MI power delivery and reception through magnetic coupling mechanisms [12].…”

Section: Introductionmentioning

confidence: 99%

A Survey on Underwater Wireless Power and Data Transfer System

Wibisono,

Alsharif,

Song

et al. 2024

IEEE Access

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This research extensively explores contemporary techniques in Underwater Wireless Power and Data Transfer (WPDT), as found in recent literature over the past 5 years. These techniques involve Magnetic Induction (MI), acoustic communication, and optical communication. The study aims to evaluate transmission efficiency, propose solutions to overcome range limitations, facilitate integration, and precisely map multilayer networks. The research methodology includes proposed solutions to address the limitations of each transmission technique, multilayer network mapping, and model validation. Evaluation is conducted on the relative efficiency of each method, including power loss at each layer, the connection matrix between layers, and transmission speed. Simulations reveal power loss at nodes in each layer and the connection matrix between layers. The power loss at each node shows random values, providing a realistic aspect close to real-world scenarios, offering in-depth insights into the characteristics and performance of multilayer networks in an underwater context. The research series, involving literature elaboration, technological approaches, illustrations, and simulations, demonstrates the effectiveness of the proposed model. Simulation results indicate the potential of this model in real-world scenarios, with tolerable power loss values, suggesting that multilayer networks could be a solution to classic challenges in underwater power and data transmission. The hope of this preliminary study is to provide new insights and make a significant contribution to understanding and designing reliable underwater power and data transfer systems in the future.

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A Review on the Recent Development in the Design and Optimization of Magnetic Coupling Mechanism of Wireless Power Transmission

Cited by 28 publications

References 124 publications

Design of magnetic coupling mechanism for wireless power transmission system based on magnetic flux analysis

Design of magnetic coupling mechanism for wireless power transmission system based on magnetic flux analysis

Development and prospects of metamaterial in wireless power transfer

A Survey on Underwater Wireless Power and Data Transfer System

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