TUNING THE ANGULAR SPEED CONTROLLER OF THE REACTIVE FLYWHEEL  OF THE NANOSATELLITE ORIENTATION SYSTEM

K.P. Akinin; V.G. Kireyev

doi:10.15407/publishing2023.64.044

No. 64 (2023), ELECTRICAL MACHINES AND APPARATUS

No. 64 (2023)

TUNING THE ANGULAR SPEED CONTROLLER OF THE REACTIVE FLYWHEEL OF THE NANOSATELLITE ORIENTATION SYSTEM

ELECTRICAL MACHINES AND APPARATUS

https://doi.org/10.15407/publishing2023.64.044

Published 2023-05-08

K.P. Akinin ⁺⁻
V.G. Kireyev ⁺⁻

K.P. Akinin

Institute of Electrodynamics of the National Academy of Sciences of Ukraine, 56 Peremogi Ave., Kiev, 03057, Ukraine

V.G. Kireyev

Institute of Electrodynamics of the National Academy of Sciences of Ukraine, 56 Peremogi Ave., Kiev, 03057, Ukraine

Article_6 PDF

Keywords

nanosatellite
reactive flywheel
brushless magnetoelectric motor
control system
angular speed sensor
angular speed controller

How to Cite

Akinin , K., and V. Kireyev. “TUNING THE ANGULAR SPEED CONTROLLER OF THE REACTIVE FLYWHEEL OF THE NANOSATELLITE ORIENTATION SYSTEM”. Proceedings of the Institute of Electrodynamics of the National Academy of Sciences of Ukraine, no. 64, May 2023, p. 044, doi:10.15407/publishing2023.64.044.

Abstract

The paper describes reactive flywheels based on brushless magnetoelectric motors for controlling the spatial orientation of satellites, developed at the Institute of Electrodynamics of the National Academy of Sciences of Ukraine. The main attention is paid to the problem of implementing a rotor angular speed and position sensor, provided that it can be integrated into the motor design. The influence of the number of feedback signal pulses per one revolution of the motor shaft on the tuning of the reactive flywheel angular speed controller is studied under the condition that the ripple range at the controller output signal is limited at a given level. The dependences of the filter time constant and the controller gains on the value of the reactive flywheel angular speed and on the number of feedback signal pulses per revolution are obtained. Reference 8, figure 5, table 1.

https://doi.org/10.15407/publishing2023.64.044

Article_6 PDF

References

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