Design Considerations to Reduce Gap Variation and Misalignment Effects for the Inductive Power Transfer System

Zheng, Cong; Ma, Hongbo; Lai, Jih-Sheng; Zhang, Lanhua

doi:10.1109/tpel.2015.2424893

Cited by 114 publications

(18 citation statements)

References 36 publications

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“…2 suits a different application, since each topology presents a different impedance. The problem of topology selection has been considered in the literature, with differing conclusions about when to use series-and parallel-resonant topologies [36], [103], [104].…”

Section: Selecting a Resonant Topologymentioning

confidence: 99%

Practical Inductive Link Design for Biomedical Wireless Power Transfer: A Tutorial

Schormans

Valente

Demosthenous

2018

IEEE Trans. Biomed. Circuits Syst.

118

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Wireless power transfer systems, particularly those based on inductive coupling, provide an increasingly attractive method to safely deliver power to biomedical implants. Although there exists a large body of literature describing the design of inductive links, it generally focuses on single aspects of the design process. There is a variety of approaches, some analytic, some numerical, each with benefits and drawbacks. As a result, undertaking a link design can be a difficult task, particularly for a newcomer to the subject. This tutorial paper reviews and collects the methods and equations that are required to design an inductive link for biomedical wireless power transfer, with a focus on practicality. It introduces and explains the published methods and principles relevant to all aspects of inductive link design, such that no specific prior knowledge of inductive link design is required. These methods are also combined into a software package (the Coupled Coil Configurator), to further simplify the design process. This software is demonstrated with a design example, to serve as a practical illustration.

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Section: Selecting a Resonant Topologymentioning

confidence: 99%

Practical Inductive Link Design for Biomedical Wireless Power Transfer: A Tutorial

Schormans

Valente

Demosthenous

2018

IEEE Trans. Biomed. Circuits Syst.

118

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“…The amplitude I pm and phase angle θ in Equation (13) can be obtained by solving Equation (16). There are…”

Section: Of 19mentioning

confidence: 99%

“…However, the resonant frequency is significantly varied as the magnetic coupling between the primary coil and secondary coil changes due to the air-gap variation, lateral misalignment, and longitudinal movement [15]. These variations will lead to changes in coefficients of the loosely coupling transformer and frequency drift, resulting in frequency detuning and decreases in efficiency and power [15][16][17][18]. Some methods using phase-locked loop (PLL) are employed for frequency tracking.…”

Section: Introductionmentioning

confidence: 99%

A Converter Based on Independently Inductive Energy Injection and Free Resonance for Wireless Energy Transfer

et al. 2019

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Strong coupling in an inductive power transfer (IPT) system will lead to difficulties in power control and loss of soft switching conditions. This paper presents an IPT system that can decouple the converter from the resonant network. In the proposed system, the energy transmission process is divided into energy injection stage and free resonance stage. In the energy injection stage, the inductor is separated from the resonance network, and the power source injects energy into the inductor independently. In the free resonance stage, the inductor is connected to the resonance network for resonating. As a benefit from the decoupling of the converter from the resonance network, the proposed IPT system is characterized by easy power control and soft switching operation. A prototype was built for experiments. The experimental results show that with a supply voltage of 300 V, coupling factor of 0.2, and load resistance of 10 Ω, the output power can be controlled nearly linearly by the time of the energy injection stage in a range of 40–60 μs, and the system works under soft switching conditions.

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“…This decrease in k and efficiency occurs more in symmetrical coils when compared to asymmetrical coils [39]. Reference [39] reports that k is less sensitive to misalignment and air gap variation when the inner diameter of the transmitter coil is greater than the outer diameter of the receiver coil, but under perfect alignment conditions, k becomes less if the inner diameter of the transmitter coil is far greater than the outer diameter of the receiver coil. It is also reported that for a large inner diameter of the receiver coil, k is more.…”

Section: Design Of the Coil Systemmentioning

confidence: 99%

Review on Contactless Power Transfer for Electric Vehicle Charging

Ravikiran

Keshri

2017

Energies

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Abstract:For the past few years the feasibility of contactless power transfer (CPT) is being explored extensively as a future solution for charging electric vehicles (EVs). Studies report that the main obstacles in CPT are low power efficiency, misalignment tolerance, cost, range and charging time anxiety. This paper presents a review based on existing literature of the CPT systems for EV charging. Different cases of CPT technologies, their principle of operation and equivalent circuit based analysis is carried out. A discussion on compensation strategies and their effectiveness are reviewed and discussed. The design of coil systems for some city electric cars has been referenced in general. At the end recommendations and conclusions are made based on the study and analysis of the information available in literature.

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Design Considerations to Reduce Gap Variation and Misalignment Effects for the Inductive Power Transfer System

Cited by 114 publications

References 36 publications

Practical Inductive Link Design for Biomedical Wireless Power Transfer: A Tutorial

Practical Inductive Link Design for Biomedical Wireless Power Transfer: A Tutorial

A Converter Based on Independently Inductive Energy Injection and Free Resonance for Wireless Energy Transfer

Review on Contactless Power Transfer for Electric Vehicle Charging

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