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Mathematical Modelling of Dynamic Yarn Path Considering the Balloon Control Ring and Yarn Elasticity in the Ring Spinning Process Based on the Superconducting Bearing Twisting Element

Research and development

Authors:

• Hossain Mahmud
  Faculty of Mechanical Engineering, Technical University of Dresden, Dresden, Germany
• Telke Christian
  Chair of Dynamics and Mechanism Design, Institute of Solid Mechanics, Technical University of Dresden, Dresden, Germany
• Abdkader Anwar
  Faculty of Mechanical Engineering, Technical University of Dresden, Dresden, Germany
• Sparing Maria
  Institute for Metallic Materials, IFW Dresden, Dresden, Germany
• Espenhahn Tilo (j/w)
• Hühne Ruben (j/w)
• Cherif Chokri
  Faculty of Mechanical Engineering, Technical University of Dresden, Dresden, Germany
• Beitelschmidt Michael
  Chair of Dynamics and Mechanism Design, Institute of Solid Mechanics, Technical University of Dresden, Dresden, Germany

Nr DOI: 10.5604/01.3001.0012.2528

Full text

references

Abstract: The productivity of the conventional ring spinning process is currently limited by the frictional heat that occurs in the ring/traveler twisting system. In the framework of a fundamental research project from the German Research Foundation (DFG), the levitation principle of superconducting magnetic bearing (SMB) was implemented as a twisting element in order to eliminate the frictional problem and thus aim, at least, to double the productivity. A mathematical model of the dynamic yarn path has already been presented considering the friction free SMB system up to an angular spindle speed of 25.000 r.p.m. In this paper, the existing theoretical model, which was developed up to 25.000 r.p.m, was further modified considering the balloon control ring and yarn elasticity at a higher angular spindle speed, such as 50.000 r.p.m. The model was solved numerically using the Runge-Kutta method. With this model, it is possible to estimate the yarn tension distribution and balloon form considering the above-mentioned parameters. The model established was further validated by comparing the yarn tension and balloon forms predicted with measured ones up to an angular spindle speed of 15.000 r.p.m in a ring spinning tester based on superconducting magnetic bearing.

Tags:

mathematical modelling, balloon control ring, yarn elasticity, yarn tension, balloon form, ring spinning, superconducting magnetic bearing.

Citation:

Hossain M, Telke C, Abdkader A, Sparing M, Espenhahu T, Hiihne R, Cherif Ch, Beitelschmidt M . Mathematical Modelling of Dynamic Yarn Path Considering the Balloon Control Ring and Yarn Elasticity in the Ring Spinning Process Based on the Superconducting Bearing Twisting Element. FIBRES & TEXTILES in Eastern Europe 2018; 26, 5(131): 32-40. DOI: 10.5604/01.3001.0012.2528

Published in issue no 5 (131) / 2018, pages 32–40.