Design of auto frequency tuning capacitive power transfer system based on class‐E
            <sup>2</sup>
            dc/dc converter

Lu, Kai; Nguang, Sing Kiong; Ji, Shengkai; Wei, Lei

doi:10.1049/iet-pel.2016.0655

Cited by 20 publications

(5 citation statements)

References 20 publications

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“…(d) Ignoring metal barriers: effective energy transfer is achieved even in the presence of metal barriers [7].…”

Section: Classificationmentioning

confidence: 99%

Wireless power transfer technologies for electric vehicles: Principles, challenges and opportunities

Bai

2023

J. Phys.: Conf. Ser.

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Wireless power transfer (WPT) technology is a promising solution for charging electric vehicles, which have many advantages such as zero emissions, low noise, and convenience. This paper reviews the current state-of-the-art of WPT technology for electric vehicles, focusing on the classification, principle, advantages, and disadvantages of different WPT methods, such as capacitive WPT, inductive WPT, microwave WPT, and laser WPT. The paper also discusses the future trends and challenges of WPT technology, such as coil design, international standards, safety issues, multiple charging modes, and compensation networks. The paper aims to provide a comprehensive overview of WPT technology for electric vehicles and to inspire further research and development in this field.

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“…(d) Ignoring metal barriers: effective energy transfer is achieved even in the presence of metal barriers [7].…”

Section: Classificationmentioning

confidence: 99%

Wireless power transfer technologies for electric vehicles: Principles, challenges and opportunities

Bai

2023

J. Phys.: Conf. Ser.

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“…Considering load variations, power flow control method [171], auto frequency tuning control method [128,172], perturb & observe (P&O)-based tracking control method [130], linear quadratic gaussian (LQG) control method [173] are proposed in CPT systems. The power flow control provides automatic regulation of the output voltage against circuit parameter variations.…”

Section: ) System Control Structuresmentioning

confidence: 99%

A Comprehensive Review on Wireless Capacitive Power Transfer Technology: Fundamentals and Applications

et al. 2022

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Capacitive power transfer (CPT) technology is becoming increasingly popular in various application areas. Due to its limitations, such as low frequency, low coupling capacitance, and the high voltage stress on metal plates, the studies on high power CPT applications fell behind previously. Therefore, the wideband gap (WBG) semiconductor devices and the compensation topologies are further adopted to tackle these limitations. The main purpose of the paper is to review CPT applications in terms of performance parameters, advantages, disadvantages and also challenges. Initially, the basic principles of CPT technology are examined, which cover compensation topologies, coupler structures, transfer distance, power electronic components, and system control methods. Then, CPT applications are evaluated for performance parameters (i.e., power level, operation frequency, system efficiency, transfer distance) along with compensation types, inverter types, and coupler types. The applications are categorized into six main groups according to industrial topics as safety, consumer electronics, transport, electric machines, biomedical, and miscellaneous. Herein, power level changes from µW to kW ranges, the operation frequency varies from 100s of kHz to 10s of MHz ranges as well. The maximum system efficiency is recorded as 97.1 %. The transfer distance varies from µm range to 100s of mm ranges. The full-bridge inverter topology and four-plate coupler structure are noticeable in CPT applications. Finally, advantages, disadvantages, and challenges of CPT applications are evaluated in detail. This review is expected to serve as a reference for researchers who study on CPT systems and their applications.INDEX TERMS Capacitive power transfer, capacitive coupling, wireless power transfer.MEHMET ZAHID EREL was born in Sakarya, Turkey. He received the B.S. degree in electrical engineering from the Yildiz Technical University, Istanbul, Turkey, in 2013, and the M.S. degree in electronics and communication engineering from the Ankara Yildirim Beyazit University, Ankara, Turkey, in 2016. He is currently pursuing the Ph.D. degree with the department of electrical and electronics engineering,

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“…To maintain ZVS for parameter variation such as coupling capacitance or load, [30] uses a control strategy by selecting a proper shunt capacitor. Some papers [21,31] also focused on maintaining ZVS without a control strategy by designing the appropriate impedance matching network. This paper follows the same approach of designing the proper impedance matching network and a shunt capacitor to achieve ZVS for the parameter variations.…”

Section: Frequency Splitting In Wpt Systemsmentioning

confidence: 99%

8-Plate Multi-Resonant Coupling Using a Class-E2 Power Converter for Misalignments in Capacitive Wireless Power Transfer

Bezawada

Dhali

2022

Electronics

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Misalignment is a common issue in wireless power transfer systems. It shifts the resonant frequency away from the operating frequency that affects the power flow and efficiency from the charging station to the load. This work proposes a novel capacitive wireless power transfer (CPT) using an 8-plate multi-resonant capacitive coupling to minimize the effect of misalignments. A single-active switch class-E2 power converter is utilized to achieve multi-resonance through the selection of different resonant inductors. Simulations show a widening of the resonant frequency band which offers better performance than a regular 4-plate capacitive coupling for misalignments. The hardware results of the 8-plate multi-resonant coupling show an efficiency of 88.5% for the 20.8 W test, which is 18.3% higher than that of the regular 4-plate coupling. Because of the wider resonant frequency band {455–485 kHz}, compared with the regular 4-plate coupling, the proposed design minimized the output voltage drop by 15% for a 10% misalignment. Even for large misalignments, the 8-plate performance improved by 40% compared with the 4-plate coupling.

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Design of auto frequency tuning capacitive power transfer system based on class‐E ² dc/dc converter

Cited by 20 publications

References 20 publications

Wireless power transfer technologies for electric vehicles: Principles, challenges and opportunities

Wireless power transfer technologies for electric vehicles: Principles, challenges and opportunities

A Comprehensive Review on Wireless Capacitive Power Transfer Technology: Fundamentals and Applications

8-Plate Multi-Resonant Coupling Using a Class-E2 Power Converter for Misalignments in Capacitive Wireless Power Transfer

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Design of auto frequency tuning capacitive power transfer system based on class‐E 2 dc/dc converter

Cited by 20 publications

References 20 publications

Wireless power transfer technologies for electric vehicles: Principles, challenges and opportunities

Wireless power transfer technologies for electric vehicles: Principles, challenges and opportunities

A Comprehensive Review on Wireless Capacitive Power Transfer Technology: Fundamentals and Applications

8-Plate Multi-Resonant Coupling Using a Class-E2 Power Converter for Misalignments in Capacitive Wireless Power Transfer

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Design of auto frequency tuning capacitive power transfer system based on class‐E ² dc/dc converter