Modeling of novel cross-type hybrid 4-pole carrier system and experimental air gap control

COMPEL Pub Date : 2024-04-16 DOI:10.1108/compel-05-2023-0193
Enes Mahmut Göker, Ahmet Fevzi Bozkurt, Kadir Erkan
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Abstract

Purpose

The purpose of this paper is to introduce a novel cross (+) type yoke with hybrid electromagnets and new reluctance modeling to precisely calculate attraction force is given.

Design/methodology/approach

The comparison of attraction force and torque analyses between the proposed formulation and the existing formulation in the literature is comparatively presented. For the correctness of the force and torque values calculated in the model created, the system was created in ANSYS Maxwell and its accuracy was proved by making analyses. The maglev carrier system is inherently unstable from the point of view of control engineering. For that, it needs an active controller to eliminate this instability. For the levitation of the carrier system, it is necessary to design a controller in three axes (z, α and β). I-PD controller was designed for the air gap control of the carrier system in three axes and the controller parameters were determined by the canonical method.

Findings

While the new formulation proposed in the modeling of the carrier system has a maximum error of 1.03%, the existing formula in the literature has an error of 16.83% in the levitation distance point.

Originality/value

A novel cross-type hybrid carrier system has been proposed in the literature. With the double integral used in modeling the system, it takes a long time to solve symbolically, and it is difficult to simulate dynamic behavior in control validation. To solve this problem, attraction force and inclination torque values are easily characterized by new formulation and besides the simulations are conducted easily. The experimental setup was manufactured and assembled, and the carrier system was successfully levitated, and reference tracking was performed without overshoot.

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新型交叉式混合 4 极载波系统建模与气隙控制实验
目的本文旨在介绍一种新型交叉(+)式混合电磁铁磁轭,并给出了精确计算吸引力的新磁阻模型。为确保所创建模型中计算的力和扭矩值的正确性,在 ANSYS Maxwell 中创建了该系统,并通过分析证明了其准确性。从控制工程的角度来看,磁悬浮运载系统本身是不稳定的。因此,它需要一个主动控制器来消除这种不稳定性。为了使载体系统悬浮,有必要在三个轴(z、α 和 β)上设计一个控制器。研究结果在载体系统建模中提出的新公式的最大误差为 1.03%,而文献中现有公式在悬浮距离点的误差为 16.83%。原创性/价值文献中提出了一种新型交叉型混合载体系统。由于系统建模采用双积分,符号求解时间长,难以在控制验证中模拟动态行为。为了解决这个问题,采用新的计算公式可以轻松表征吸引力和倾斜力矩值,而且易于进行仿真。实验装置已制造完成并组装完毕,载体系统悬浮成功,并进行了无过冲的参考跟踪。
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