Design and Analysis of a Rectangular PCB Printed Magnetorquer for Nanosatellites

CubeSats have become increasingly important in the last two decades and are playing a very important role in the space industry, especially with Earth-oriented nanosatellites. Earth-oriented nanosatellites require more precise attitude control when there is a requirement for good pointing accuracy....

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Bibliographic Details
Published in:IEEE journal on miniaturization for air and space systems 2021-09, Vol.2 (3), p.105-111
Main Authors: Ali, Hassan, Islam, Qamar ul, Mughal, Muhammad Rizwan, Mahmood, Rehan, Anjum, Muhammad Rizwan, Reyneri, Leonardo M.
Format: Article
Language:English
Subjects:
Active control
Actuators
Attitude control
Circuit boards
Coils
Control systems
Cubesat
Design analysis
Design optimization
Internal dimensions
Low earth orbits
Magnetic fields
Magnetic moments
magnetorquer
modular
nanosatellite
Nanosatellites
optimum
Parameters
Passive control
Power consumption
printed
Printed circuits
reconfigurable
scalable
Space vehicles
Thermal analysis
Torque
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Summary:CubeSats have become increasingly important in the last two decades and are playing a very important role in the space industry, especially with Earth-oriented nanosatellites. Earth-oriented nanosatellites require more precise attitude control when there is a requirement for good pointing accuracy. In such missions, passive control systems are not suitable due to their low accuracy, hence, active control systems are used. Different types of actuators are available, but magnetic actuators are best suited for low-Earth orbit (LEO) nanosatellites. When current moves through the wire, a magnetic field is generated which is used to generate torque. The torque generated makes it possible to control the attitude of the satellite in the desired direction. The best option for nanosatellites is to use the printed or embedded magnetorquers due to its scalable, reconfigurable, and modular approach. Printing the magnetorquer into the internal layers of the printed circuit board (PCB) reduce the harness complexities and space constraints effectively. The optimized design of the printed magnetorquer is selected by analyzing various parameters, such as turn width, distance between two turns, applied voltage, external dimensions, and internal dimensions. The design also takes into consideration other parameters, such as generated torque, torque-to-power ratio, magnetic field to current ratio, consumed power, rotation time, and thermal analysis, by changing the optimizing variables and taking into account the most important key design drivers. The design selection and results of the analysis concerning the selection of optimized parameters are presented.
ISSN:2576-3164
2576-3164
DOI:10.1109/JMASS.2020.3029489