Abstract
The performance of a nonlinear position-velocity controller in stabilising the lateral vibrations of a rotor-active magnetic-bearings system (RAMBS) is investigated. Cubic nonlinear position-velocity and linear position-velocity controllers are introduced to stabilise RAMBS lateral oscillations. According to the proposed control law, the nonlinear system model is established and then investigated with perturbation analysis. Nonlinear algebraic equations that govern the steady-state oscillation amplitudes and the corresponding phases are derived. Depending on the obtained algebraic equations, the different frequency response curves and bifurcation diagrams are plotted for the studied model. Sensitivity analysis for the linear and nonlinear controllers’ gains is explored. Obtained analytical results demonstrated that the studied model had symmetric bifurcation behaviours in both the horizontal and vertical directions. In addition, the integration of the cubic position controller made the control algorithm more flexible to reshape system dynamical behaviours from the hardening spring characteristic to the softening spring characteristic (or vice versa) to avoid resonance conditions. Moreover, the optimal design of the cubic position gain and/or cubic velocity gain could stabilise the unstable motion and eliminate the nonlinear effects of the system even at large disc eccentricities. Lastly, numerical validations for all acquired results are performed, where the presented simulations show accurate correspondence between numerical and analytical investigations.
Highlights
Saeed et al [15,16] explored the nonlinear dynamics of the constant stiffness coefficient 16-pole rotor active magnetic bearings system (AMBS) (RAMBS)
The stability of the obtained solution (i.e., the solution of Equations (37)–(40)) can be investigated by checking the eigenvalues of the Jacobian matrix of the dynamical system given by Equations (31)–(34)
Slow-flow autonomous differential equations that govern system vibration amplitudes and the modified phases were derived. The influence of both the linear and nonlinear control gains on the system dynamics were explored through different response curves and bifurcation diagrams
Summary
Saeed et al [2,3] discussed the nonlinear dynamical characteristics of a 6-pole RAMBS, and applied the linear position-velocity controller in both Cartesian control configuration [2]. Saeed et al [15,16] explored the nonlinear dynamics of the constant stiffness coefficient 16-pole RAMBS They investigated system oscillatory behaviours in the case of both the Cartesian and radial control configurations utilising the linear positionvelocity controller as the main control algorithm. Saeed et al [25,26,27,28] applied different control schemes of the position and velocity controllers to suppress the lateral oscillations of the rotating shafts using the 4-pole AMBS. The plotted response curves revealed that the considered system had symmetric bifurcation behaviours in both the horizontal and vertical directions
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