Efficient Transfer of the Medium Frequency Magnetic Field Using Anisotropic Metamaterials

Steckiewicz, Adam

doi:10.3390/en16010334

Cited by 2 publications

(1 citation statement)

References 38 publications

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“…Although WPT technology has many applications, the increasing power transmission distance often results in a decrease in transmission efficiency, as well as an urgent need to address safety concerns. Metamaterials offer a way to improve efficiency and reduce flux density in WPT systems [31,32]. The authors of [31] present an overview of the status and technological challenges facing metamaterial-based WPT systems.…”

Section: Introductionmentioning

confidence: 99%

Analysis of the Wireless Power Transfer System Using a Finite Grid of Planar Circular Coils

Stankiewicz

2023

Energies

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In this paper was analysed a wireless power transfer system (WPT) with multiple resonators supplying, for example, sensors or LED lighting. Energy is transferred simultaneously using a group of identical planar spiral circular coils acting as transmitters and receivers. These coils were arranged to form transmitting and receiving planes. The receivers were connected to independent power supply circuits of each, e.g., sensor or LED lighting. Higher power reliability and flexibility can be achieved by isolating these circuits. The proposed system was described and discussed. Taking into account the skin effect and mutual couplings, a theoretical analysis was made. A detailed analysis was made at the resonant frequency of the system. The system was modeled using a matrix equation and appropriate formulas. The calculations were verified experimentally for different loads and two distances between transmitters and receivers. The efficiency and receiver power were compared and discussed. The maximum efficiency was about 45% at the small distance between the planes. The maximum efficiency of the WPT system decreased more than two times to less than 20% when the distance between the coils was doubled. The results and discussion of the conducted analysis may provide valuable knowledge when designing this type of system.

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Section: Introductionmentioning

confidence: 99%

Analysis of the Wireless Power Transfer System Using a Finite Grid of Planar Circular Coils

Stankiewicz

2023

Energies

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Analysis of the Influence of the Skin Effect on the Efficiency and Power of the Receiver in the Periodic WPT System

Stankiewicz

2023

Energies

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The article shows an analysis of the influence of the skin effect on the maximum efficiency and maximum power of a receiver in a wireless power transfer system (WPT). For this purpose, the original solution of the WPT system was used, which contained periodically arranged planar coils. The results concern the multi-variant analysis of the WPT system. The geometry of the coils was taken into account, i.e., the size of coils, the number of turns, as well as the distance between the transmitting and receiving coils. The calculations were carried out over the frequency range of 0.1–1 MHz. In order to analyse the influence of the skin effect on the proposed WPT system, two approaches were used: analytical and numerical. The article analyses the appropriate selection of load impedance in order to obtain maximum efficiency or maximum power of the receiver. In this analysis, the influence of the skin effect on each of the two operating procedures was examined. The obtained analytical and numerical results differed by no more than 0.45%, which confirmed the correctness of the proposed WPT model. Based on the results, it was determined that the greatest influence of the skin effect occurred at 1 MHz. Then, the efficiency decreased by no more than 9%, while in the case of the receiver power decreased by an average of 25%. Detailed analysis shows the influence of the skin effect on the system parameters, and can also be an important element in the design of WPT systems.

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Efficient Transfer of the Medium Frequency Magnetic Field Using Anisotropic Metamaterials

Cited by 2 publications

References 38 publications

Analysis of the Wireless Power Transfer System Using a Finite Grid of Planar Circular Coils

Analysis of the Wireless Power Transfer System Using a Finite Grid of Planar Circular Coils

Analysis of the Influence of the Skin Effect on the Efficiency and Power of the Receiver in the Periodic WPT System

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