Vibration Analysis of Elevator Rope  (Comparison between Experimental Results and Calculated Results)

Headframe resonance is a major cause of large hoist system damage and instability. Therefore, restraining the resonance of a large hoist system headframe is critical for reducing shock and vibrations, thereby maintaining the safety and reliability of the mining equipment. In this study, an approach was developed to restrain the resonance of a large hoist system headframe. A finite element model of a large hoist system headframe was established. Simulations were carried out, and the modal characteristics of the large hoist system headframe were obtained. The results showed that the second- and third-order natural frequencies were both close to 1.5[Formula: see text]Hz. Furthermore, experiments were conducted. An analysis of the experimental and simulation results indicated that a vibrational forcing with a frequency of 1.56[Formula: see text]Hz was a key factor causing resonance of the large hoist system headframe. Moreover, 14 different retrofitting approaches were proposed to change the natural frequencies of the large hoist system headframe, thereby providing resonance restraint. The main retrofitting concept is to add new assembled steel box structures with inner stiffeners between the transverse beams and oblique brackets in the middle area of the large hoist system headframe. In addition, the weight added by the retrofitting approach should be minimized to reduce the construction difficulties and costs. After a comprehensive comparison, an optimal retrofitting design of the 14 retrofitting approaches considered was selected. This optimal retrofitting approach provides guidance for restraining the resonance of large hoist system headframes. Furthermore, this study provides a method for the design of large hoist system headframes and the determination of the vibration characteristics.

show abstract

Adaptive boundary control for a friction hoisting system during the loading process

Wang,

Cao

2024

Transactions of the Institute of Measurement and Control

View full text Add to dashboard Cite

This paper aims at the rope dynamic tension fluctuation (DTF) control in the friction hoisting system (FHS) during the loading process. The exact dynamic modelling of the tail and head ropes connected to the cage is considered. A disturbance observer is proposed to track the actual impact disturbance. The actuator acts at the friction wheel to pretension the system. The use of an adaptive neural network allows for the handling of system uncertainty. An appropriate control law is developed to stabilize the cage and suppress the rope DTF in FHS during the loading process. Numerical simulations and theoretical analysis are presented to prove the feasibility and effectiveness of the proposed control law. Numerical analysis results show that the head rope dynamic displacement fluctuation (DDF) and DTF amplitudes can be suppressed to at least 1/125 of their initial fluctuation amplitudes under the proposed control law.

show abstract

Vibration Analysis of Elevator Rope (Comparison between Experimental Results and Calculated Results)

Cited by 5 publications

References 10 publications

Study on longitudinal vibration of friction hoist skips based on Ritz series

Study on longitudinal vibration of friction hoist skips based on Ritz series

Study on the Resonance Restraint of a Large Hoist System Headframe

Adaptive boundary control for a friction hoisting system during the loading process

Contact Info

Product

Resources

About