Opportunities and Challenges for Near-Field Wireless Power Transfer: A Review

Jawad, Aqeel Mahmood; Nordin, Rosdiadee; Gharghan, Sadik Kamel; Jawad, Haider Mahmood; Ismail, Mahamod

doi:10.3390/en10071022

Cited by 201 publications

(141 citation statements)

References 122 publications

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“…There are mainly two ways to realize a charging station: the first one is based on electrical contacts between the base station and the drone [6]. The second solution is based on the wireless power transfer (WPT) technology [7][8][9][10][11][12][13]. The contact-based solution allows high power transfer efficiency but the presence of contacts exposed to atmospheric agents will reduce the efficiency and reliability of the system.…”

Section: Introductionmentioning

confidence: 99%

Wireless Power Transfer Technology Applied to an Autonomous Electric UAV with a Small Secondary Coil

2018

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This study deals with the design and the optimization of a wireless power transfer (WPT) charging system based on magnetic resonant coupling applied to an electric vertical take-off and landing Unmanned Aerial Vehicle (UAV). In this study, a procedure for primary and secondary coil design is proposed. The primary circuit in the ground station consists of an array of coils in order to mitigate the negative effects on the coupling factor produced by the possible misalignment between the coils due to an imperfect landing. Key aspects for the design of the secondary coil onboard the UAV are the lightness and compactness of the WPT system components. A demonstrative prototype of the WPT system is applied to a commercial drone. The WPT electrical performances are calculated and measured. Finally, an automatic battery recharge station is built where the drone can autonomously land, recharge the battery and take off to continue its flight mission.

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Section: Introductionmentioning

confidence: 99%

Wireless Power Transfer Technology Applied to an Autonomous Electric UAV with a Small Secondary Coil

2018

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“…Applications are the charging of, for example, electric vehicles [8], automatic guided vehicles [9], biomedical implants [10], integrated circuits [11] and low-power consumer applications [12]. Compared to IWPT, it has several advantages, such as a reduced cost and weight and the ability to transfer energy through metal [13,14]. Just as for IWPT, CWPT allows for the charging of multiple receivers at once with one transmitter.…”

Section: Introductionmentioning

confidence: 99%

Optimal Analytical Solution for a Capacitive Wireless Power Transfer System with One Transmitter and Two Receivers

Minnaert

Stevens

2017

Energies

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Wireless power transfer from one transmitter to multiple receivers through inductive coupling is slowly entering the market. However, for certain applications, capacitive wireless power transfer (CWPT) using electric coupling might be preferable. In this work, we determine closed-form expressions for a CWPT system with one transmitter and two receivers. We determine the optimal solution for two design requirements: (i) maximum power transfer, and (ii) maximum system efficiency. We derive the optimal loads and provide the analytical expressions for the efficiency and power. We show that the optimal load conductances for the maximum power configuration are always larger than for the maximum efficiency configuration. Furthermore, it is demonstrated that if the receivers are coupled, this can be compensated for by introducing susceptances that have the same value for both configurations. Finally, we numerically verify our results. We illustrate the similarities to the inductive wireless power transfer (IWPT) solution and find that the same, but dual, expressions apply.

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“…WPT technology has been widely studied in different applications like electric vehicle charging, consumer electronics charging, radio-frequency identification (RFID) devices, bio implantable devices, and many more [1,2]. WPT techniques are broadly classified into near field and far field power transfer methods.…”

Section: Introductionmentioning

confidence: 99%

Class E Power Amplifier Design and Optimization for the Capacitive Coupled Wireless Power Transfer System in Biomedical Implants

et al. 2017

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Abstract:The capacitive coupled wireless power transfer (CCWPT) operating at megahertz (MHz) frequency is broadly considered as the promising solution for low power biomedical implants. The class E power amplifier is attractive in MHz range wireless power transfer (WPT) applications due to zero voltage switching (ZVS) and zero voltage derivative switching (ZVDS) properties. The existing design of class E amplifier is investigated only for inductive resonant coupled (IRC) WPT systems; the modelling and optimization of the class E amplifier for CCWPT systems are not deliberated with load variation. Meanwhile, the variations in the coupling distance and load are common in real time applications, which could reduce the power amplifier (PA) efficiency. The purpose of this paper is to model and optimize the class E amplifier for CCWPT systems used in MHz range applications. The analytical model of PA parameters and efficiency are derived to determine the optimal operating conditions. Also, an inductive-capacitive-inductive (LCL) impedance matching network is designed for the robust operation of the PA, which improves the efficiency and maintains required impedance compression. The maximum efficiency of the proposed design reached up to 96.34% at 13.56 MHz and the experimental results are closely matched with the simulation.

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Opportunities and Challenges for Near-Field Wireless Power Transfer: A Review

Cited by 201 publications

References 122 publications

Wireless Power Transfer Technology Applied to an Autonomous Electric UAV with a Small Secondary Coil

Wireless Power Transfer Technology Applied to an Autonomous Electric UAV with a Small Secondary Coil

Optimal Analytical Solution for a Capacitive Wireless Power Transfer System with One Transmitter and Two Receivers

Class E Power Amplifier Design and Optimization for the Capacitive Coupled Wireless Power Transfer System in Biomedical Implants

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