Thermal Enhancement of Permeability-Gradient Nanocrystalline Toroidal Core With Uniform Magnetic Flux Density Distribution

IF 6.5 1区工程技术 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE Transactions on Power Electronics Pub Date : 2025-01-03 DOI:10.1109/TPEL.2024.3523890

Chen Chen;C. Q. Jiang;Sheng Ren;Weisheng Guo;Tianlu Ma;Zhichao Luo

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Abstract

Inductors are the essential components in electronic devices, but the nonuniform magnetic flux density distribution (MFDD) in toroidal cores will lead to premature saturation and reduced material utilization. To address this problem, we propose a nanocrystalline toroidal core with a permeability gradient (PG) along the radius direction. The permeability of the nanocrystalline flake ribbon (NFR) can be easily adjusted through a physical crushing process, providing the fabrication condition for the PG-NFR core. The influence of the sublayer number and the PG are simulated and investigated by finite-element analysis. In the experiment, four NFR cores are fabricated, and temperature rises are measured and compared. For a core with uniform permeability (μ = 1500), the inner temperature rises to 92.2 °C, while the outer side reaches 82.86 °C, resulting in a maximum difference of 9.34 °C. In contrast, the core with a PG (μ = 1600–2200) shows only a 2.51 °C discrepancy. Simulation and experimental results are in high agreement, indicating that the PG-NFR core achieves a more uniform MFDD.

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磁通密度分布均匀的磁导率梯度纳米晶环形磁芯的热增强

电感器是电子器件的重要组成部分，但环形磁芯的磁通密度分布不均匀会导致电感器过早饱和，降低材料利用率。为了解决这个问题，我们提出了一个沿半径方向具有渗透率梯度（PG）的纳米晶环形岩心。通过物理破碎工艺可以很容易地调节纳米晶片带（NFR）的磁导率，为制备PG-NFR芯提供了条件。通过有限元分析，模拟和研究了子层数和PG的影响。在实验中，制作了四个NFR芯，并测量和比较了温升。对于磁导率均匀（μ = 1500）的岩心，内部温度可达92.2℃，外部温度可达82.86℃，最大温差为9.34℃。相比之下，具有PG （μ = 1600-2200）的岩心只有2.51°C的差异。仿真结果与实验结果吻合较好，表明PG-NFR核实现了较为均匀的MFDD。

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来源期刊

IEEE Transactions on Power Electronics 工程技术-工程：电子与电气

CiteScore

15.20

自引率

20.90%

发文量

1099

审稿时长

3 months

期刊介绍： The IEEE Transactions on Power Electronics journal covers all issues of widespread or generic interest to engineers who work in the field of power electronics. The Journal editors will enforce standards and a review policy equivalent to the IEEE Transactions, and only papers of high technical quality will be accepted. Papers which treat new and novel device, circuit or system issues which are of generic interest to power electronics engineers are published. Papers which are not within the scope of this Journal will be forwarded to the appropriate IEEE Journal or Transactions editors. Examples of papers which would be more appropriately published in other Journals or Transactions include: 1) Papers describing semiconductor or electron device physics. These papers would be more appropriate for the IEEE Transactions on Electron Devices. 2) Papers describing applications in specific areas: e.g., industry, instrumentation, utility power systems, aerospace, industrial electronics, etc. These papers would be more appropriate for the Transactions of the Society which is concerned with these applications. 3) Papers describing magnetic materials and magnetic device physics. These papers would be more appropriate for the IEEE Transactions on Magnetics. 4) Papers on machine theory. These papers would be more appropriate for the IEEE Transactions on Power Systems. While original papers of significant technical content will comprise the major portion of the Journal, tutorial papers and papers of historical value are also reviewed for publication.