Design and Analysis of Inductive Power Transfer System Using Nanocrystalline Flake Ribbon Core

Yibo Wang; C. Q. Jiang; Chen Chen; Xiaosheng Wang; Xinru Li; Teng Long

doi:10.1109/JESTPE.2024.3358857

Design and Analysis of Inductive Power Transfer System Using Nanocrystalline Flake Ribbon Core

Yibo Wang, C. Q. Jiang^*, Chen Chen, Xiaosheng Wang, Xinru Li, Teng Long

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

12 Citations (Scopus)

53 Downloads (CityUHK Scholars)

Abstract

This paper proposes the design and analysis of an inductive power transfer (IPT) system that features novel nanocrystalline flake ribbon (NFR) cores. The flake ribbons are produced by compressing the dielectric material with nanocrystalline ribbons, leading to a reduction in the eddy current loss. A complete magnetic core is then fabricated by laminating the ribbons, imparting anisotropic properties. The paper outlines the design methodology for NFR cores, considering this lamination characteristic in Double-D IPTs. Accordingly, NFR cores with a lamination factor of 0.375 and a core thickness of 3.2 mm have been designed, produced, and experimentally validated. The tests indicate an over 95% DC-DC efficiency and an over 96.3% AC-AC efficiency at the output power of 8.9 kW. To assess their thermal attributes, one-hour duration tests at continuous 6.6 kW operation were performed on NFR cores and ferrite groups. Results demonstrate that NFR cores maintain a cooler temperature at 76.4 °C, whereas the DMR44 and DMR95 reach 91.7 °C and 84.9 °C respectively. Additionally, the designed NFR cores have achieved 51% core weight reduction, 31% volume reduction, and 20% thickness reduction. The proposed NFR cores based on the design methodology can greatly enhance high power density IPT systems. © 2024 IEEE.

Original language	English
Pages (from-to)	3334-3347
Journal	IEEE Journal of Emerging and Selected Topics in Power Electronics
Volume	12
Issue number	4
Online published	26 Jan 2024
DOIs	https://doi.org/10.1109/JESTPE.2024.3358857
Publication status	Published - Aug 2024

Funding

This work was supported in part by the Natural Science Foundation of China, China, under Grant 52107011, in part by the Science Technology and Innovation Committee of Shenzhen Municipality, China, under Grant SGDX20210823104003034, in part by the Research Grants Council, Hong Kong SAR under ECS Grant 21200622, in part by the Environment and Conservation Fund (ECF), Hong Kong SAR under Grant ECF 36/2021

Research Keywords

Inductive power transfer (IPT)
nanocrystalline core
flake ribbon
magnetics design

Publisher's Copyright Statement

COPYRIGHT TERMS OF DEPOSITED POSTPRINT FILE: © 2024 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for all other uses, in any current or future media, including reprinting/republishing this material for advertising or promotional purposes, creating new collective works, for resale or redistribution to servers or lists, or reuse of any copyrighted component of this work in other works. Wang, Y., Jiang, C., Chen, C., Wang, X., Li, X., & Long, T. (2024). Design and Analysis of Inductive Power Transfer System Using Nanocrystalline Flake Ribbon Core. IEEE Journal of Emerging and Selected Topics in Power Electronics, 12(4), 3334 – 3347. https://doi.org/10.1109/JESTPE.2024.3358857

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abstract = "This paper proposes the design and analysis of an inductive power transfer (IPT) system that features novel nanocrystalline flake ribbon (NFR) cores. The flake ribbons are produced by compressing the dielectric material with nanocrystalline ribbons, leading to a reduction in the eddy current loss. A complete magnetic core is then fabricated by laminating the ribbons, imparting anisotropic properties. The paper outlines the design methodology for NFR cores, considering this lamination characteristic in Double-D IPTs. Accordingly, NFR cores with a lamination factor of 0.375 and a core thickness of 3.2 mm have been designed, produced, and experimentally validated. The tests indicate an over 95% DC-DC efficiency and an over 96.3% AC-AC efficiency at the output power of 8.9 kW. To assess their thermal attributes, one-hour duration tests at continuous 6.6 kW operation were performed on NFR cores and ferrite groups. Results demonstrate that NFR cores maintain a cooler temperature at 76.4 °C, whereas the DMR44 and DMR95 reach 91.7 °C and 84.9 °C respectively. Additionally, the designed NFR cores have achieved 51% core weight reduction, 31% volume reduction, and 20% thickness reduction. The proposed NFR cores based on the design methodology can greatly enhance high power density IPT systems. {\textcopyright} 2024 IEEE.",

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author = "Yibo Wang and Jiang, {C. Q.} and Chen Chen and Xiaosheng Wang and Xinru Li and Teng Long",

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AU - Long, Teng

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AB - This paper proposes the design and analysis of an inductive power transfer (IPT) system that features novel nanocrystalline flake ribbon (NFR) cores. The flake ribbons are produced by compressing the dielectric material with nanocrystalline ribbons, leading to a reduction in the eddy current loss. A complete magnetic core is then fabricated by laminating the ribbons, imparting anisotropic properties. The paper outlines the design methodology for NFR cores, considering this lamination characteristic in Double-D IPTs. Accordingly, NFR cores with a lamination factor of 0.375 and a core thickness of 3.2 mm have been designed, produced, and experimentally validated. The tests indicate an over 95% DC-DC efficiency and an over 96.3% AC-AC efficiency at the output power of 8.9 kW. To assess their thermal attributes, one-hour duration tests at continuous 6.6 kW operation were performed on NFR cores and ferrite groups. Results demonstrate that NFR cores maintain a cooler temperature at 76.4 °C, whereas the DMR44 and DMR95 reach 91.7 °C and 84.9 °C respectively. Additionally, the designed NFR cores have achieved 51% core weight reduction, 31% volume reduction, and 20% thickness reduction. The proposed NFR cores based on the design methodology can greatly enhance high power density IPT systems. © 2024 IEEE.

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Design and Analysis of Inductive Power Transfer System Using Nanocrystalline Flake Ribbon Core

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ECS: Enhancement of the Newly Developed Nanocrystalline Ribbon Bidirectional Wireless EV Charging System

ECF: Development of a New Nanocrystalline Alloy WPT4 High Energy-efficiency Wireless Charger for Electric Vehicle

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Design and Analysis of Inductive Power Transfer System Using Nanocrystalline Flake Ribbon Core

Abstract

Funding

Research Keywords

Publisher's Copyright Statement

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ECS: Enhancement of the Newly Developed Nanocrystalline Ribbon Bidirectional Wireless EV Charging System

ECF: Development of a New Nanocrystalline Alloy WPT4 High Energy-efficiency Wireless Charger for Electric Vehicle

Cite this