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Methods for the Qualitative Assessment of Functional and Operational Properties of Polymer Textile Materials

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Fibre Chemistry Aims and scope

Methods for the qualitative assessment of functional and operational properties of polymer textile materials based on mathematical modeling, computer forecasting, and system analysis of their deformation processes are described. Such a qualitative assessment forms the basis for obtaining recommendations for the design of new polymer textile materials having specified functional properties.

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References

  1. A.G. Makarov, Izv. Vuzov. Tekhnol. Tekst. Prom-sti [In Russian], No. 2, 12-16 (2000).

  2. A.G. Makarov, Izv. Vuzov. Tekhnol. Tekst. Prom-sti [In Russian], No. 2, 13-17 (2002).

  3. A.G. Makarov, N.V. Pereborova et al., Khim. Volokna [In Russian], No. 5, 44-47 (2013).

  4. V.V. Golovina, P.P. Rymkevich et al., Khim. Volokna [In Russian], No. 6, 33-40 (2013).

  5. P.P. Rymkevich, A.A. Romanova et al., J. Macromol. Sci. Part B: Physics, 52, No. 12, 1829-1847 (2013).

    Article  CAS  Google Scholar 

  6. A.G. Makarov, G.Y. Slutsker, and N.V. Drobotun, Techn. Phys., 60, No. 2, 240-245 (2015).

    Article  CAS  Google Scholar 

  7. A.G. Makarov, G.Ya. Slutsker et al., Fizika Tverd. Tela [In Russian], 58, No. 4, 814-820 (2015).

  8. A.G. Makarov, A.V. Demidov et al., Khim. Volokna [In Russian], No. 6, 60-67 (2015).

  9. A.G. Makarov, N.V. Pereborova et al., Khim. Volokna [In Russian], No. 6, 68-72 (2015).

  10. A.G. Makarov, N.V. Pereborova et al., Izv. Vuzov. Tekhnol. Tekst. Prom-sti [In Russian], No. 5 (359), 48-58 (2015).

  11. A.G. Makarov, A.V. Demidov et al., Izv. Vuzov. Tekhnol. Tekst. Prom-sti [In Russian], No. 6 (360), 194-205 (2015).

  12. A.G. Makarov, N.V. Pereborova et al., Khim. Volokna [In Russian], No. 1, 37-42 (2016).

  13. A.G. Makarov, A.V. Demidov et al., Khim. Volokna [In Russian], No. 2, 52-58 (2015).

  14. A.V. Demidov, A.G. Makarov et al., Izv. Vuzov. Tekhnol. Tekst. Prom-sti [In Russian], No. 1 (367), 250-258 (2017).

  15. A.G. Makarov, N.V. Pereborova et al., Izv. Vuzov. Tekhnol. Tekst. Prom-sti [In Russian], No. 2 (368), 309-313 (2017).

  16. A.G. Makarov, N.V. Pereborova et al., Izv. Vuzov. Tekhnol. Tekst. Prom-sti [In Russian], No. 4 (370), 287-292 (2017).

  17. A.G. Makarov, N.V. Pereborova et al., Khim. Volokna [In Russian], No. 1, 69-73 (2017).

  18. A.G. Makarov, N.V. Pereborova et al., Khim. Volokna [In Russian], No. 2, 59-63 (2017).

  19. A.V. Demidov, A.G. Makarov et al., Khim. Volokna [In Russian], No. 4, 46-51 (2015).

  20. N.V. Pereborova, A.V. Demidov et al., Khim. Volokna [In Russian], No. 2, 36-39 (2018).

  21. A.G. Makarov, N.V. Pereborova et al., Khim. Volokna [In Russian], No. 3, 94-97 (2018).

  22. N.V. Pereborova, A.G. Makarov et al., Khim. Volokna [In Russian], No. 4, 54-56 (2018).

  23. A.G. Makarov, N.V. Pereborova et al., Khim. Volokna [In Russian], No. 4, 117-120 (2018).

  24. N.V. Pereborova, A.G. Makarov et al., Khim. Volokna [In Russian], No. 5, 89-92 (2019).

  25. N.V. Pereborova, A.G. Makarov et al., Khim. Volokna [In Russian], No. 6, 3-6 (2018).

  26. N.V. Pereborova, A.G. Makarov et al., Khim. Volokna [In Russian], No. 6, 87-90 (2018).

  27. N.V. Pereborova, A.V. Demidov et al., Izv. Vuzov. Tekhnol. Tekst. Prom-sti [In Russian], No. 2 (374), 251-255 (2018).

  28. N.V. Pereborova, A.G. Makarov et al., Izv. Vuzov. Tekhnol. Tekst. Prom-sti [In Russian], No. 3 (375), 253-257 (2018).

  29. N.V. Pereborova, A.G. Makarov et al., Khim. Volokna [In Russian], No. 5, 68-70 (2019).

  30. N.V. Pereborova, A.G. Makarov et al., Khim. Volokna [In Russian], No. 5, 71-73 (2019).

  31. N.V. Pereborova, A.V. Demidov et al., Izv. Vuzov. Tekhnol. Tekst. Prom-sti [In Russian], No. (380), 192-198 (2019).

  32. N.V. Pereborova, A.V. Demidov et al., Izv. Vuzov. Tekhnol. Tekst. Prom-sti [In Russian], No. 3 (381), 242-247 (2019).

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The study was financed under the state assignment of the Ministry of Science and Higher Education of the Russian Federation, Project No. FSEZ-2020-0005 and under the grant of the President of the Russian Federation No. MK-1210.2020.8.

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Authors and Affiliations

  1. Saint Petersburg State University of Industrial Technologies and Design, St. Petersburg, Russia

    M.A. Egorova, I.M. Egorov, N.V. Pereborova & A.A. Makarova

Authors
  1. M.A. Egorova
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  2. I.M. Egorov
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  3. N.V. Pereborova
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  4. A.A. Makarova
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Corresponding author

Correspondence to N.V. Pereborova.

Additional information

Translated from Khimicheskie Volokna, No. 4, July-August, pp. 68-70, 2020.

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Egorova, M., Egorov, I., Pereborova, N. et al. Methods for the Qualitative Assessment of Functional and Operational Properties of Polymer Textile Materials. Fibre Chem 52, 302–305 (2020). https://doi.org/10.1007/s10692-021-10201-5

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  • DOI: https://doi.org/10.1007/s10692-021-10201-5

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