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ISSN (Print): 1872-2121
ISSN (Online): 2212-4047

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Review Article

Review on Main Drive Torsional Vibration and Roller Coupling Vibration of Rolling Mill

Author(s): Xiao Bin Fan*, Bin Zhao, Yu Jiang and Bing Xu Fan

Volume 15, Issue 3, 2021

Published on: 21 April, 2020

Page: [301 - 313] Pages: 13

DOI: 10.2174/1872212114999200421150533

Price: $65

Abstract

Background: Rolling mill vibration has become one of the most widespread and unsolved problems in the rolling industry, which is called "Ghost" vibration. The research on the starting mechanism, vibration characteristics and vibration suppression measures of high-speed tandem rolling mill has always been a hotspot and difficult point in the field of rolling at home and abroad. However, up to now, the research on rolling mill vibration has not formed a relatively complete and widely accepted theoretical system, experimental means and solutions. In production, vibration is often controlled by experience and test, which has a high cost and low efficiency.

Methods: In this paper, the research history and achievements of vibration phenomena, vibration mechanism, the stability of the rolling process and vibration control theory of high-speed tandem rolling mill in recent years are summarized. The aim is to reveal the mechanism of rolling mill vibration in the continuous rolling process, the mechanism of rolling mill non-linear vibration instability and its changing law, and to explore the optimization of rolling process and the control method of rolling mill structure so as to improve the rolling process.

Results: The evolution of non-linear random torsional / bending vibration and its transfer mechanism to the space coupling vibration of the roll system, the unsteady dynamic friction characteristics of the rolling interface and the mechanism of induced roll chatter, and the non-linear random dynamic behavior of the space coupling vibration of the roll system are revealed.

Conclusion: The stability of the rolling process can realize the research and development of highend products considering the stability of the rolling process, and also provide a reference for further research by industry experts.

Keywords: Rolling mill, vibration, nonlinearity, stability, coupling, torsional vibration.

Graphical Abstract

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