轴对称磁体分区谐波优化方法

IF 2.1 3区工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Transactions on Magnetics Pub Date : 2024-12-12 DOI:10.1109/TMAG.2024.3516373

Oscar Sucre;Stefan Glöggler

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引用次数: 0

摘要

提出了一种适用于轴对称磁源设计的基于磁场区域谐波描述的优化方法。得到磁场轴向分量$B_{z}$和径向分量$B_{\rho}$的表达式，表示为纬向谐波的无穷和。对于以轴向磁化圆柱体为基本构件的排列，也导出了所有纬向动量$M_{l}$的解析公式，直至11阶（$l=11$）。通过这些公式建立的关系，启动了优化程序，以找到满足设计期望目标的永磁环排列。给出了两个应用实例：一对环排列（PRA）最均匀的梯度场和四环排列（FRA）最均匀的磁场。针对PRA和FRA两种情况，找到了几种优化配置。对于厚度较薄的PRA，所发现的几何条件再现了产生梯度的已知麦克斯韦电流环路对的几何条件。在上下环间距半径为28%的区域内，这样实现的梯度均匀性达到0.5%。对于间隙为300 mm的FRA配置，报告了7种配置，提供了98.1至82.2 mT之间的场强。在最佳情况下，不均匀性为100 ppm，占间隙的40%。利用有限元分析（FEA）计算出的场强线与通过径向和轴向分量序列表达式计算出的场强线相匹配，证实了所发现的FRA结构符合设计目标。此外，所获得的均匀性与文献中报道的其他轴对称核磁共振成像（MRI）配置的其他设计相比较。然而，所发现的联邦铁路局结构以其更简单的结构而与众不同。讨论了该方法在电子光学或磁致动器磁透镜设计中的应用。

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Optimization Method Based on Zonal Harmonics for Axially Symmetric Magnets

An optimization method based on the zonal harmonic description of the magnetic field, suitable for the design of axially symmetric magnetic sources, is presented. Expressions of both axial

$B_{z}$

and radial

$B_{\rho }$

components of the magnetic field are obtained as the infinite sum of the zonal harmonics. For arrangements having as the basic building block an axially magnetized cylinder, analytical formulas for all zonal momenta

$M_{l}$

have also been derived up to the 11th order (

$l=11$

). Through the relationships established by these formulas, a procedure of optimization is initiated to find arrangements of permanent magnet rings that fulfill wished goals of design. Two examples of application have been presented: a pair of rings arrangement (PRA) for a maximally homogeneous gradient field and the four-ring arrangement (FRA) for a maximally homogeneous magnetic field. Several optimized configurations have been found, both for the PRA and FRA cases. For the PRA of thin thickness, geometrical conditions found reproduce those of the known Maxwell pair of current loops for the generation of gradients. The uniformity in gradients so achieved reaches 0.5% within a region with radius 28% of the gap between the lower and upper rings. For the FRA configurations with a gap of 300 mm, seven configurations are reported, providing a field strength between 98.1 and 82.2 mT. The inhomogeneity is 100 ppm at 40% of the gap in the best case. A match of the field lines calculated using finite-element analysis (FEA) with those calculated through the serial expressions of the radial and axial components confirms the compliance of the found FRA configurations with the goals of the design imposed. Furthermore, the homogeneity obtained compares well with the other designs reported in other axially symmetric configurations for magnetic resonance imaging (MRI) presented in the literature. The found FRA configurations, however, distinguish themself by their more simple structure. Discussions about the application of the method in the design of magnetic lenses for electron optics or magnetic actuators have also been included.

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来源期刊

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

CiteScore

4.00

自引率

14.30%

发文量

565

审稿时长

4.1 months

期刊介绍： Science and technology related to the basic physics and engineering of magnetism, magnetic materials, applied magnetics, magnetic devices, and magnetic data storage. The IEEE Transactions on Magnetics publishes scholarly articles of archival value as well as tutorial expositions and critical reviews of classical subjects and topics of current interest.