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Formation Mechanism and Influence Factors of Roll Surface Oil Film Thickness in the Double Cold Reduction Mill

Author

Listed:
  • Cheng Qian
  • Zhenhua Bai
  • Jiasheng Zhang
  • Yaya Cui
  • Changchun Hua

Abstract

In the double cold rolling process, the emulsion entering the roll gap during the double cold rolling process has the characteristics of high concentration and small flow rate so that the roll surface oil film thickness will affect roll gap oil film thickness, which in turn affects the rolling friction coefficient. This paper analyzes the formation mechanism and evolution process of the roll surface oil film thickness by considering the equipment and process characteristics of the emulsion direct injection application lubrication system. Then, based on the principle of fluid dynamics, the roll surface oil film thickness model in the double cold rolling process is established, and the prediction of the roll surface oil film thickness during the double cold rolling process is realized. Subsequently, the effects of five factors, such as rolling speed, work roll roughness, maximum contact stress between rolls, emulsion initial dynamic viscosity, and emulsion pressure viscosity coefficient, on the roll surface oil film thickness are quantitatively analyzed, and the corresponding influence laws are given. Finally, the relevant model and software that are applied to the 1220 double cold reduction mill have achieved good results.

Suggested Citation

  • Cheng Qian & Zhenhua Bai & Jiasheng Zhang & Yaya Cui & Changchun Hua, 2020. "Formation Mechanism and Influence Factors of Roll Surface Oil Film Thickness in the Double Cold Reduction Mill," Mathematical Problems in Engineering, Hindawi, vol. 2020, pages 1-10, May.
    • Handle: RePEc:hin:jnlmpe:6746828
    DOI: 10.1155/2020/6746828
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