Development of methods to control quality of the structure of cross-wound packages

Authors

DOI:

https://doi.org/10.15587/1729-4061.2018.143825

Keywords:

defects of winding, defects of structure, tape winding, braid winding, shear of turns, turn reversal point

Abstract

The process of winding is one of the principal processes in the textile industry. Quality of the formed packages largely defines the quality of the finished product in the textile industry, as well as labor productivity and equipment performance. Therefore, attention to analysis of processes of package formation, construction of new promising methods and designs of winding mechanisms, has been growing for many decades. We address issues related to the analysis of control methods over the structure of the cross-wound winding used in spinning production. The structure of winding is understood in the present work as the mutual arrangement of threads when they are laid on the surface of the package. Thus, the parameters of the structure include such quantities as a turn lifting angle, a distance between the points of turn reversal, a step in turns, etc.

It is known that the mutual arrangement of turns on the winding body when packages are frictionally driven is not homogeneous. Under certain ratios between rotation speed of the bobbin and motion frequency of the thread guide, the threads are laid on the same place. In this case, the so-called braid formations are observed. If motion frequencies of the bobbin and the thread guide differ slightly from the multiple ones, turns are placed close to each other, in this case, a tape winding is formed. The braid winding is accompanied by a number of phenomena, which negatively affect quality of the formed packages. In this case, the shear and displacement parameters are determined based on empirical data. To substantiate the approach to choosing the technological parameters for such mechanisms, we performed a theoretical analysis of the process of braid structures formation in terms of the force interactions between threads. To make such a choice, it is necessary to have an instrumental procedure for quantifying the winding structure parameters, which is why we have in detail investigated methods for their registration.

Author Biographies

Mahammadali Nuraddin Nuriyev, Azerbaijan State Economic University (UNEC) Istiglaliyyat str., 6, Baku, Azerbaijan, AZ 1001

Doctor of Technical Sciences, Professor

Department of Standardization and Certification

Ilham Mammad Seydaliyev, Azerbaijan State Economic University (UNEC) Istiglaliyyat str., 6, Baku, Azerbaijan, AZ 1001

PhD, Associate Professor

Department of Standardization and Certification

References

  1. Praček, S., Pušnik, N., Simončič, B., Tavčer Petra, F. (2015). Model for Simulating Yarn Unwinding from Packages. Fibres and Textiles in Eastern Europe, 23 (2 (110)), 25–32. Available at: http://www.fibtex.lodz.pl/article1407.html
  2. Liangxue, L. (2015). Control System for Textile WindingMachine Convenient for Loading of Bobbin. IPC: B65H54/547, B65H63/00, B65H67/04, CN104386539 (A).
  3. Shams Nateri, A., Ebrahimi, F., Sadeghzade, N. (2014). Evaluation of Yarn Defects by Image Processing Technique. Optik – International Journal for Light and Electron Optics, 125 (20), 5998–6002. doi: https://doi.org/10.1016/j.ijleo.2014.06.095
  4. Rudovsky, P. N. (1995). Influence of Parameters of the Winding Mechanism on Laying Coils in Tourniquet Formation. News of Higher Educational Institutions, Technology of Textile Industry, 6, 108–111.
  5. Fu, J., Yun, J., Kim, J.-S., Jung, Y. (2015). Real-time graphic visualization of filament band winding for fiber-reinforced cylindrical vessels. Journal of Composite Materials, 50 (16), 2165–2175. doi: https://doi.org/10.1177/0021998315602325
  6. Li, L. (2014). Pat. No. 104386539A CN. Control System for Textile Winding Machine Convenient for Loading of Bobbin. IPC: B65H54/547, B65H63/00, B65H67/04. No. 201410607590 CN. declareted: 03.11.2014; published: 04.03.2015.
  7. Ashhepkova, N. S. (2015). Mathcad in the kinematic and dynamic analysis of the manipulator. Eastern-European Journal of Enterprise Technologies, 5 (7 (77)), 54–63. doi: https://doi.org/10.15587/1729-4061.2015.51105
  8. Jhatial, R. A., Peerzada, M. H., Syed, U. (2016). Optical Yarn Assessment System for Twist Measurement in Rotor-Spun Yarn. Mehran University Research Journal of Engineering and Technology, 34 (1), 25–32.
  9. Nuriyev, M. N., Seydaliyev, I. M., Recebov, I. S., Dadashova, K. S., Musayeva, T. T. (2017). Determining the dependences for calculating a conversion scale of profile height of the controlled packing surface. Eastern-European Journal of Enterprise Technologies, 2 (1 (86)), 58–62. doi: https://doi.org/10.15587/1729-4061.2017.96977
  10. Maag, F. (1985). Spinnspulen mit der Stufenprazissionswicklung. Textilindustrie, 6, 416–420.
  11. Nuriyev, M. N., Musayeva, T. T. (2016). Development of Algorithms Surface Recognition Forging Cross Winding. Bulletin of NTU “KhPI”. Series: Mechanical-technological systems and complexes, 49 (1221), 52–55.
  12. Nuriyev, M., Ali Veliyev, F., İnsaf Hamidov, H., Aqagul Sailov, R., Mahamad Seydaliyev, I., Zargar Jabbarova, G. (2018). Development of a Device for Continuously Monitoring the Parameters of the Winding Structure of Textile Bobbins. Ingeniería solidaria, 14 (24), 1. doi: https://doi.org/10.16925/.v14i24.2183
  13. Nuriyev, M. N. (2016). Destructive Methods of Controlling the Density Distribution of the Winding Body. Progressive Technologies and Systems of Mechanical Engineering, 4 (55), 44–48.
  14. Nuriyev, M., Dadashova, K., Radzhabov, I. (2016). Development of methods for recognition of structural defects using package surface image. ScienceRise, 4 (2 (21)), 6–10. doi: https://doi.org/10.15587/2313-8416.2016.66143
  15. Ganira, Z. D., Nuriev, M. N. (2017). Formirovanie pakovok s sinusoidal'nym izmeneniem skorosti nitevoditelya. Izvestiya vysshih uchebnyh zavedeniy. Tekhnologiya tekstil'noy promyshlennosti, 2, 176–180.
  16. Nuriyev, M., Veliev, F., Seydaliyev, I. M., Dadashova, K., Jabbarova, G. Z., Allahverdiyeva, I. (2017). Analysis of the formation of filament winding in terms of force interactions between threads. Eastern-European Journal of Enterprise Technologies, 6 (1 (90)), 11–18. doi: https://doi.org/10.15587/1729-4061.2017.118961
  17. Musayeva, T. T., Nuriyev, M. N. (2016). Efficiency of Quality Management System’s Application In The Enterprises of Light Industry. International Journal of Humanities & Social Science Studies (IJHSSS), II (VI), 233–240. Available at: http://oaji.net/articles/2016/1115-1464938939.pdf
  18. Nuriev, M. N., Kiselev, P. N. (2007). Razrabotka algoritmov avtomatizirovannogo opredeleniya edinichnyh pokazateley dlya ocenki defektov formy pakovok krestovoy namotki. Uchenye zapiski AzTU. Seriya: Fundamental'nye nauki, 3, 19–22.
  19. Denisov, A. R., Kiprina, L. Yu., Rudovskiy, P. N. (2006). Primenenie metodov klasternogo analiza dlya kontrolya kachestva pakovok krestovoy namotki. Izvestiya vysshih uchebnyh zavedeniy. Tekhnologiya tekstil'noy promyshlennosti, 4s, 111–113.

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Published

2018-10-05

How to Cite

Nuriyev, M. N., & Seydaliyev, I. M. (2018). Development of methods to control quality of the structure of cross-wound packages. Eastern-European Journal of Enterprise Technologies, 5(1 (95), 61–70. https://doi.org/10.15587/1729-4061.2018.143825

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Section

Engineering technological systems