Abstract
Fast rotating machines require special attention to ensure accurate rotor placement within the air gap. For this reason, the active magnetic bearings (AMB) system is used to levitate the rotor in the air gap using an electromagnetic feedback control force. The contact-less support AMB system improves the rotor dynamic performance and helps in the success of machine operations. However, the control design for the five degrees-of-freedom (DOF) AMB system is intricate because of its complex nonlinear dynamics. Moreover, these systems are often subjected to model uncertainties, harmonic disturbances, and sensor noises. Therefore, this paper proposes a robust control strategy using an adaptive second-order non-singular fast terminal sliding mode control (SMC) design. The proposed control law employs the higher-order SMC scheme to alleviate the chattering problem from the discontinuous SMC input, which would otherwise restrict its practical applicability. Further, a non-singular fast terminal sliding surface is selected to achieve a faster system response. The adaptive law estimates the switching gain to relax the upper bound assumption of disturbance. The theoretical stability analysis of the proposed methodology proves the finite-time convergence of system states to a small residual bound in the neighborhood of zero. The numerical analysis with a comparative study is also carried out to illustrate the efficacy of the proposed strategy.
Highlights
The rotor mass anomaly in a fast rotating machine causes the rotor to vibrate like a harmonic disturbance
This paper investigates the controller design for a five DOF active magnetic bearing (AMB) system subjected to multiple challenges such as parametric model uncertainties, external disturbances, and sensor noises
This paper aims to develop a stabilizing control law for the uncertain AMB system that suspends the rotor inside the nominal air gap
Summary
The rotor mass anomaly in a fast rotating machine causes the rotor to vibrate like a harmonic disturbance. The controller is designed based on a priori upper bound knowledge of disturbance This assumption is relaxed in [27], [38], where adaptive-based integral second and third-order SMC schemes are presented for the AMB system, respectively. These schemes prove the finite-time stability of system states, their convergence time is comparatively large, and the input chattering is still evident in the control response of [38]. This paper investigates the controller design for a five DOF AMB system subjected to multiple challenges such as parametric model uncertainties, external disturbances, and sensor noises In this regard, a new robust controller is proposed using an adaptive gain-based second-order non-singular fast terminal SMC (ASNFTSMC) design.
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