Modeling of technological parameters of filament joints of clothing parts for professional sports fencing

Authors

DOI:

https://doi.org/10.15587/2706-5448.2020.202199

Keywords:

fencing clothes, knitted joints quality, seam strength, seam deformation, quality control.

Abstract

The object of the presented research is the technological process of manufacturing clothes for professional sports fencing. The subject of research is the quality of the knitted joints, which are regulated by technical requirements and require special attention when designing an assortment of clothes for fencing athletes.

The research methodology is based on the analysis of scientific literature, measurement of mechanical properties and modeling of technological parameters of knitted joints of fencing clothes. In order to determine the effect of the number of stitches on the breaking strength and the longitudinal deformation of the knitted joints of fencing clothes, mathematical modeling of the manufacturing process using the experimental design method is used. The choice of the experimental design is associated with determining the number of experimental points and their placement in the factor space, which will make it possible to obtain the necessary information for making a decision with a relatively small number of experiments. During the study, methods were used to determine the breaking strength and extended deformation of the joints. A feature of the study is the determination of rational technological parameters of the knitted joints while maintaining the necessary tensile strength and a certain level of longitudinal deformation. The rational parameters of the number of stitches in the seam-sewn and finishing stitching lines for the studied materials of fencing clothes are those for which the tensile strength of the seam is ≥970 N and the longitudinal deformation does not exceed ± 2.0%, namely: t– (5.0÷6.5) stitches/10 mm, h–(3.0÷3.5) stitches/10 mm.

The obtained results prove the possibility of using mathematical modeling methods to predict the quality of knitted joints of clothing parts for professional sports fencing. This approach is of practical importance and can be applied both at the stage of designing the technology of manufacturing clothes for professional sports fencing when choosing processing modes for new materials, and at the stage of manufacturing and quality control of performed operations.

Author Biographies

Julia Kharchenko, Kyiv National University of Technologies and Design, 2, Nemyrovicha-Danchenko str., Kyiv, Ukraine, 01011

Researcher

Analytical and Research Testing Laboratory «Textile-TEST»

Larysa Bilotska, Kyiv National University of Technologies and Design, 2, Nemyrovicha-Danchenko str., Kyiv, Ukraine, 01011

PhD, Associate Professor

Department of Technology and Design of Sewing Products

References

  1. Chen, T. L.-W., Wong, D. W.-C., Wang, Y., Ren, S., Yan, F., Zhang, M. (2017). Biomechanics of fencing sport: A scoping review. PLOS ONE, 12 (2), e0171578. doi: http://doi.org/10.1371/journal.pone.0171578
  2. Frère, J., Göpfert, B., Nüesch, C., Huber, C., Fischer, M., Wirz, D., Friederich, N. F. (2010). Kinematical and EMG-Classifications of a Fencing Attack. International Journal of Sports Medicine, 32 (1), 28–34. doi: http://doi.org/10.1055/s-0030-1267199
  3. Laputin, A. M., Hamalii, V. V., Arkhypov, O. A. et. al. (2005). Biomekhanika sportu. Kyiv: Olimpiiska literatura, 320.
  4. Wylde, J. M., Tan, F. H. Y., O’Donoghue, G. P. (2013). A time-motion analysis of elite women’s foil fencing. International Journal of Performance Analysis in Sport, 13 (2), 365–376. doi: http://doi.org/10.1080/24748668.2013.11868654
  5. Mezhdunarodnye pravila provedeniia sorevnovanii po fekhtovaniiu. Available at: http://nffu.org.ua
  6. Roi, G. S., Bianchedi, D. (2008). The science of fencing: Implications for performance and injury prevention. Sports Medicine, 38 (6), 465–481. doi: http://doi.org/10.2165/00007256-200838060-00003
  7. Barth, B. (2006). The Complete Guide to Fencing. Meyer & Meyer Verlag.
  8. Kharchenko, Yu. M., Dmytrenko, L. A., Bilotska, L. B., Statsenko, V. V., Ocheretna, L. V. (2016). Research of shape stability of the knitted fabric for fencing clothing under dynamic and static loads. Technology Audit and Production Reserves, 5 (3 (31)), 38–46. doi: http://doi.org/10.15587/2312-8372.2016.81202
  9. Beskin, N., Galavska, L. (2014). Research of knit for fencing suits on resistance against perforation. Book of Proceedings. 47th International Congress IFKT. Izmir, 50–54.
  10. Gurarda, A. (2019). Seam Performance of Garments. Textile Manufacturing Processes. doi: http://doi.org/10.5772/intechopen.86436
  11. Song, G. (Ed.) (2011). Improving Comfort in Clothing. Woodhead Publishing, 496. doi: http://doi.org/10.1533/9780857090645
  12. Koketkin, P. P., Safronova, I. V., Kochegura, T. N. (1989). Puti uluchsheniia kachestva izgotovleniia odezhdy. Moscow: Legprombytizdat, 240.
  13. Gurarda, A., Meric, B. (2005). Sewing Needle Penetration Forces and Elastane Fiber Damage during the Sewing of Cotton/Elastane Woven Fabrics. Textile Research Journal, 75 (8), 628–633. doi: http://doi.org/10.1177/0040517505057640
  14. Rajput, B., Kakde, M., Gulhane, S., Mohite, S., Raichurkar, P. P. (2018). Effect of sewing parameters on seam strength and seam efficiency. Trends in Textile Engineering and Fashion Technology, 4 (1), 4–5. doi: http://doi.org/10.31031/tteft.2018.04.000577
  15. Bubonia, J. E. (2014). Apparel Quality. Fairchild Books, 350. doi: http://doi.org/10.5040/9781501303265
  16. Pozdniakov, B. P. (1933). Raschet prochnosti shvov. Moscow: Gizlegprom, 100.
  17. Bedenko, V. E., Polushkin, A. A. (2003). Raschetnyi metod prognozirovaniya prochnosti nitochnyh soedinenii. Tekhnicheskii tekstil, 7. Available at: http://rustm.net/catalog/article/556.html
  18. Bedenko, V. E., Polushkin, A. A. (2003). Prochnost petel na razryv. Tekhnicheskii tekstil, 6. Available at: http://rustm.net/catalog/article/631.html
  19. Levkov, K. L., Figovskii, O. V. (2012). Innovatsionnyi protsess i innovatsionnyi inzhener. Inzhenernyi vestnik Dona, 2, 787–799.
  20. Chizhik, M. A., Volkov, V. Ia. (2012). Graficheskie optimizatsionnye modeli mnogoparametricheskikh tekhnologicheskikh protsessov legkoi promyshlennosti. Inzhenernyi vestnik Dona, 2, 87–94.
  21. Slizkov, A. M., Shcherban, V. V., Krasnytskyi, S. M. et. al. (2013). Prohnozuvannia fizyko-mekhanichnykh vlastyvostei tekstylnykh materialiv pobutovoho pryznachennia. Kyiv: KNUTD, 223.
  22. Bilotska, L. B., Bilei-Ruban, N. V. (2006). Zastosuvannia matematychnykh modelei pry rozviazanni zadach optymizatsii protsesiv shveinoho vyrobnytstva. Visnyk Khmelnytskoho natsionalnoho universytetu, 3, 7–9.
  23. Tikhomirov, V. B. (1974). Planirovanie i analiz eksperimenta (pri provedenii issledovanii v legkoi i tekstilnoi promyshlennosti). Moscow: Legkaia industriia, 262.

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Published

2020-03-05

How to Cite

Kharchenko, J., & Bilotska, L. (2020). Modeling of technological parameters of filament joints of clothing parts for professional sports fencing. Technology Audit and Production Reserves, 2(3(52), 31–34. https://doi.org/10.15587/2706-5448.2020.202199

Issue

Vol. 2 No. 3(52) (2020): Chemical engineering

Section

Reports on research projects

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Copyright (c) 2020 Julia Kharchenko, Larysa Bilotska

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