Loss Estimation and Thermal Analysis of a Magnetic Levitation Reaction Flywheel with PMB and AMB for Satellite Application

He, Zhimin; Tong, Wen; Liu, Xu; Suo, Yuchen

doi:10.3390/en15041584

Cited by 4 publications

(2 citation statements)

References 23 publications

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“…et al [19] proposed an experimental approach to study the loss factor and efficiency of an active magnetic thrust bearing. Zan et al [20] combined thermal network analysis with the temperature field distribution to obtain the key factors affecting the heat dissipation of the flywheel. Kepsu, D. et al [21] analyzed the influence of segmentation of the magnets on losses.…”

Section: Of 20mentioning

confidence: 99%

Simulation and Experiment Analysis of Temperature Field of Magnetic Suspension Support Based on FBG

Cong

Cui

et al. 2022

Sensors

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Temperature rise is an important factor limiting the development of magnetic suspension support technology. Traditional temperature sensors such as thermocouples are complicated and vulnerable to electromagnetic interference due to their point contact temperature measurement methods. In this paper, the equivalent model of magnetic suspension support is established, and the temperature field is simulated and analyzed by magnetic thermal coupling calculation in ANSYS software. Then, a quasi-distributed temperature measurement system is designed, and the FBG temperature sensor is introduced to measure the temperature of the magnetic suspension support system by “one-line and multi-point”. By comparing the analysis experiments and simulations, the equivalent accuracy of the simulation model and the FBG temperature sensor can accurately measure the temperature of the magnetic suspension support.

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Section: Of 20mentioning

confidence: 99%

Simulation and Experiment Analysis of Temperature Field of Magnetic Suspension Support Based on FBG

Cong

Cui

et al. 2022

Sensors

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“…Magnetic levitation technology has garnered significant interest in various applications, including chip manufacturing [1][2][3][4], microscopic imaging [5][6][7][8], and force control [9][10][11][12]. Its advantages of being friction-less [13], non-polluting [14], and having high precision capabilities [15] make it highly desirable. Presently, multiple processing methods, such as extreme ultraviolet lithography [16][17][18], require workbenches to carry workpieces between several stations.…”

Section: Introductionmentioning

confidence: 99%

Force and Torque Model of Magnetically Levitated System with 2D Halbach Array and Printed Circuit Board Coils

Zou,

Song,

Zhou

et al. 2023

Sensors

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Precision machining fields often require worktables with different stroke sizes. To address the need for scalability and facilitate manufacturing, this study proposes a novel infinite expansion magnetically levitated planar motor (MLPM) based on PCB stator coils. Different from existing magnetic levitation systems that use PCB coils, the design presented in this paper utilizes smaller coil units, with each coil being independent of one another. The coils are structured in a spiral pattern on a 16-layer PCB, comprising 15 layers of coils, while the last layer is dedicated to wiring and other circuits. Magnetic field modeling is conducted for both the stator coil and the 2D Halbach array structure employed in the system. A simple table lookup method is employed to accurately account for the prevalent end effects observed during system motion. Additionally, the decoupling effect of magnetic force and torque is evaluated by solving for the current vector at different points along a specific trajectory. To verify the accuracy of the proposed system’s modeling, a prototype is developed and tested. Experimental results demonstrate that compared to traditional harmonic model methods, the proposed approach improves the calculation accuracy of magnetic force by 50.31% and torque by 70.65%. This study presents a new MLPM system with vast potential applications in precision manufacturing and robotics. The innovative design and improved performance characteristics make it a promising technology for enhancing the capabilities of worktables in precision machining fields.

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Finite element simulation of iron losses for an Active Magnetic Bearing–Rotor system constructed of Hiperco laminations

Koufopanos,

Nikolakopoulos

2024

Simulation Modelling Practice and Theory

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Loss Estimation and Thermal Analysis of a Magnetic Levitation Reaction Flywheel with PMB and AMB for Satellite Application

Cited by 4 publications

References 23 publications

Simulation and Experiment Analysis of Temperature Field of Magnetic Suspension Support Based on FBG

Simulation and Experiment Analysis of Temperature Field of Magnetic Suspension Support Based on FBG

Force and Torque Model of Magnetically Levitated System with 2D Halbach Array and Printed Circuit Board Coils

Finite element simulation of iron losses for an Active Magnetic Bearing–Rotor system constructed of Hiperco laminations

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