Adaptive Sliding Mode Control Strategy for Horizontal Vibration of High-speed Elevator Based on Model Identification

Abstract

The transverse vibration equation of a high-speed elevator car system is established to address the problem of passenger comfort due to transverse vibration caused by the unevenness of guide rails. The Hankel-Toeplitz model of transverse vibration is derived by considering the excitation-response hysteresis phenomenon. The least-squares method is used to identify the model parameters of the car system by combining the measured vibration acceleration data of the high-speed elevator. Then, the model's accuracy is verified by comparing the modeled response with the measured vibration response. Further, based on the theory of sliding mode variable structure control, an adaptive sliding mode active damping control strategy is designed for instantaneous power, and the comparative analysis of vibration acceleration and displacement of the car system under sliding mode control under light and heavy load conditions and different control strategies is carried out by MATLAB to verify the feasibility and effectiveness of the proposed control strategy parameter identification model.