Design and Implementation of Novel Homopolar Magnetic Bearings Incorporated in Reaction Wheel for Satellite Attitude Control

Ding Cheng Hsiao; Min Fu Hsieh

doi:10.1109/ACCESS.2023.3290308

Design and Implementation of Novel Homopolar Magnetic Bearings Incorporated in Reaction Wheel for Satellite Attitude Control

Ding Cheng Hsiao, Min Fu Hsieh

Department of Electrical Engineering

Research output: Contribution to journal › Article › peer-review

5 Citations (Scopus)

Abstract

A novel compact-design homopolar magnetic bearing system is proposed for reaction wheels in satellite applications. The magnetic bearings, with low core loss, can increase the designed speed of the reaction wheel, thereby reducing the rotor inertia and wheel mass required to achieve attitude control. The proposed magnetic bearings are capable of producing both radial and axial suspension forces using a simple L-shaped core structure. The magnetic bearings thus not only simplify the control logic, but also enable the radial and axial forces to be independently controlled. A magnetic circuit model of the proposed bearing system is first derived and validated by finite element simulations. The practical feasibility of the bearing system is then confirmed experimentally using a prototype reaction wheel, which is designed through the developed magnetic circuit model.

Original language	English
Pages (from-to)	66374-66381
Number of pages	8
Journal	IEEE Access
Volume	11
DOIs	https://doi.org/10.1109/ACCESS.2023.3290308
Publication status	Published - 2023

All Science Journal Classification (ASJC) codes

General Computer Science
General Materials Science
General Engineering

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10.1109/ACCESS.2023.3290308

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title = "Design and Implementation of Novel Homopolar Magnetic Bearings Incorporated in Reaction Wheel for Satellite Attitude Control",

abstract = "A novel compact-design homopolar magnetic bearing system is proposed for reaction wheels in satellite applications. The magnetic bearings, with low core loss, can increase the designed speed of the reaction wheel, thereby reducing the rotor inertia and wheel mass required to achieve attitude control. The proposed magnetic bearings are capable of producing both radial and axial suspension forces using a simple L-shaped core structure. The magnetic bearings thus not only simplify the control logic, but also enable the radial and axial forces to be independently controlled. A magnetic circuit model of the proposed bearing system is first derived and validated by finite element simulations. The practical feasibility of the bearing system is then confirmed experimentally using a prototype reaction wheel, which is designed through the developed magnetic circuit model.",

author = "Hsiao, {Ding Cheng} and Hsieh, {Min Fu}",

note = "Publisher Copyright: {\textcopyright} 2013 IEEE.",

year = "2023",

doi = "10.1109/ACCESS.2023.3290308",

language = "English",

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T1 - Design and Implementation of Novel Homopolar Magnetic Bearings Incorporated in Reaction Wheel for Satellite Attitude Control

AU - Hsiao, Ding Cheng

AU - Hsieh, Min Fu

PY - 2023

Y1 - 2023

N2 - A novel compact-design homopolar magnetic bearing system is proposed for reaction wheels in satellite applications. The magnetic bearings, with low core loss, can increase the designed speed of the reaction wheel, thereby reducing the rotor inertia and wheel mass required to achieve attitude control. The proposed magnetic bearings are capable of producing both radial and axial suspension forces using a simple L-shaped core structure. The magnetic bearings thus not only simplify the control logic, but also enable the radial and axial forces to be independently controlled. A magnetic circuit model of the proposed bearing system is first derived and validated by finite element simulations. The practical feasibility of the bearing system is then confirmed experimentally using a prototype reaction wheel, which is designed through the developed magnetic circuit model.

AB - A novel compact-design homopolar magnetic bearing system is proposed for reaction wheels in satellite applications. The magnetic bearings, with low core loss, can increase the designed speed of the reaction wheel, thereby reducing the rotor inertia and wheel mass required to achieve attitude control. The proposed magnetic bearings are capable of producing both radial and axial suspension forces using a simple L-shaped core structure. The magnetic bearings thus not only simplify the control logic, but also enable the radial and axial forces to be independently controlled. A magnetic circuit model of the proposed bearing system is first derived and validated by finite element simulations. The practical feasibility of the bearing system is then confirmed experimentally using a prototype reaction wheel, which is designed through the developed magnetic circuit model.

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Design and Implementation of Novel Homopolar Magnetic Bearings Incorporated in Reaction Wheel for Satellite Attitude Control

Abstract

All Science Journal Classification (ASJC) codes

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