Management of Multiple-Transmitter Multiple-Receiver Wireless Power Transfer Systems Using Improved Current Distribution Control Strategy

Cai, Weikun; Lai, Xiaojun; Ma, Dongtang; Tang, Houjun; Hashmi, Khurram Azeem; Xu, Junzhong

doi:10.3390/electronics8101160

Cited by 3 publications

(1 citation statement)

References 37 publications

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“…As per schemes using a Single Transmitter and Multiple Receivers (SIMO), they are adopted to recharge multiple devices with a single transmitter [13][14][15][16][17][18][19][20][21][22][23][24][25][26][27][28]. In [20] the use of a multiple-output scheme is suggested for the recharge of electric vehicles.…”

Section: Introductionmentioning

confidence: 99%

Optimal Terminations for a Single-Input Multiple-Output Resonant Inductive WPT Link

et al. 2020

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This paper analyzes a resonant inductive wireless power transfer link using a single transmitter and multiple receivers. The link is described as an (N+1)–port network and the problem of efficiency maximization is formulated as a generalized eigenvalue problem. It is shown that the desired solution can be derived through simple algebraic operations on the impedance matrix of the link. The analytical expressions of the loads and the generator impedances that maximize the efficiency are derived and discussed. It is demonstrated that the maximum realizable efficiency of the link does not depend on the coupling among the receivers that can be always compensated. Circuital simulation results validating the presented theory are reported and discussed.

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Section: Introductionmentioning

confidence: 99%

Optimal Terminations for a Single-Input Multiple-Output Resonant Inductive WPT Link

et al. 2020

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An Empirical Survey on Wireless Inductive Power Pad and Resonant Magnetic Field Coupling for In-Motion EV Charging System

et al. 2023

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EVs are the recent emerging automotive technology in the transportation sector to reduce the CO2 emission from the internal combustion engine. The issues in EVs technology development are battery tube capacity, heavy-size batteries, fast charging, and safe charging infrastructure. The dynamic wireless charging technology shows a suitable alternative to address the charging system-related issues in EV. However, a limited number of review studies are conducted to specifically address the wireless charging pad design challenges. The wireless inductive power pad and magnetic coupling circuit design are the main factors to decide the performance of the DWPT system. This review analyzes the current developments and challenges associated with wireless charging pad design. Further, this study investigates the potential parameters which improve the performance of a DWPT system to increase the distance traveled (mileage). First, this paper discusses WRIPT technology for DWPT EV charging application, and several parameters affecting the PTE are examined. Also, the aids factors considered for designing the DWPT power pad and different magnetic resonance coupling topologies are presented. In addition, the performance evaluation of the WRIPT power pad, with in-motion testing from the major findings in earlier studies is discussed. Finally, the challenges and opportunities of the WRIPT power pad for in-motion EV charging applications are also addressed. The current state of the art of DWPT and its future directions to make DWPT EV charging systems a fullfledged method are highlighted.

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Compact multi-coil inductive power transfer system with a passive peak detector circuit for wireless sensor nodes

Bouattour

Kallel

Viehweger

et al. 2022

Tm - Technisches Messen

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In Inductive Power Transfer (IPT) the misalignment between sending and receiving coils is critical and significantly influences both transfer efficiency and charging time. It can be compensated by the use of multiple coils on the sender side. However, by increasing the number of sending coils, the supply circuit becomes big, complex and not easy to control. In this paper, we propose a compact and efficient supply circuit for multi-coil IPT systems, which activates only the coil under the receiving coil. The receiver detection is based on a compact passive peak voltage detector measuring the sending coil voltage variation. The receiver coil position determination is supported by measurements of the sending coil neighbours voltages, so that a stable power transfer to battery-free wireless sensor nodes can be realized. The investigation of the influence of the type, the shape, and the size of conductive materials between sender and receiver shows that the system can distinguish between the receiver coil and different metallic objects such as iron, coins, and copper.

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Management of Multiple-Transmitter Multiple-Receiver Wireless Power Transfer Systems Using Improved Current Distribution Control Strategy

Cited by 3 publications

References 37 publications

Optimal Terminations for a Single-Input Multiple-Output Resonant Inductive WPT Link

Optimal Terminations for a Single-Input Multiple-Output Resonant Inductive WPT Link

An Empirical Survey on Wireless Inductive Power Pad and Resonant Magnetic Field Coupling for In-Motion EV Charging System

Compact multi-coil inductive power transfer system with a passive peak detector circuit for wireless sensor nodes

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