Improvement of the Dyeing Properties of 100% Polyester Fabrics Via Chitosan Application

Yıl 2024, Cilt: 34 Sayı: 2, 185 - 200, 30.06.2024

Burcu Sancar Beşen , Pınar Parlakyiğit

https://doi.org/10.32710/tekstilvekonfeksiyon.1239246

Öz

In this experimental study, it was aimed to research the possibilities of improving the dyeing properties of 100% polyester fabrics. For this purpose, the polyester fabrics were pretreated with sodium hydroxide and chitosan. The hydrophility of the pretreated fabrics were researched and they were then dyed with acid dye at 90 ⁰C. After dyeing processes, the CIEL*a*b* color values, color strength, fastness properties (to washing, water, perspiration, and rubbing) of dyed samples were investigated, and the bursting strength of the undyed and dyed samples was also tested. The results showed that it is possible to improve the dyeing properties of 100% polyester fabrics via chitosan application and that the polyester fabrics can be dyed with acid dyes at low temperatures after being cationized with chitosan following the NaOH application.

Anahtar Kelimeler

Polyester, polyester dyeing, chitosan, cationization, acid dye

Kaynakça

• 1. Jamaliniya, S., Samei, N., Shahidi, S. 2019. Using low temperature plasma for surface modification of polyester fabric: dyeing and printing improvement. The Journal of The Textile Institute 110:5, 647-651.
• 2. Jalali, S., Rezaei, R., Afjeh, MG, Eslahi, N. 2019. Effect of Vanilla as a Natural Alternative to Traditional Carriers in Polyester Dyeing with Disperse Dyes. Fibers and Polymers Vol.20, No.1, 86-92.
• 3. Najafzadeh, N., Habibi, S., Ghasri, MA. 2018. Dyeing of Polyester with Reactive Dyestuffs Using Nano-Chitosan. Journal of Engineered Fibers and Fabrics 13(2), 47-51.
• 4. Pasquet, V., Perwuelz, A., Behary, N., Isaad, J. 2013.Vanillin, a potential carrier for low temperature dyeing of polyester fabrics. Journal of Cleaner Production. 43, 20-26.
• 5. Ristić, N., Jovančić, P., Ristić, I., Jocic, D. 2012. One-bath dyeing of polyester/cotton blend with reactive dye after alkali and chitosan treatment. Industria Textilă 63(4):190-197.
• 6. Gedik, G., Avinc, O., Yavas, A., Khoddami, A. 2014. A Novel Eco-friendly Colorant and Dyeing Method for Poly(ethylene terephthalate) Substrate, Fibers and Polymers 15(2), 261- 272.
• 7. Harifi, T., Montazer, M. 2013. Free carrier dyeing of polyester fabric using nano TiO2. Dyes and Pigments 97(3), 440-445.
• 8. Bhuiyan, M.A.R, Ali, A., Islam, A., Hannan, M. A., Kabir, S. M. F., Islam, MN. 2018. Coloration of polyester fiber with natural dye henna (Lawsonia inermis L.) without using mordant: a new approach towards a cleaner production. Fashion and Textiles 5(1), 1-11.
• 9. Vavilova, S.Y., Prorokova, NP, Kalinnikov, Y.A. 2003. The problem of cyclic oligomers in dyeing and processing polyester and ways of solving it. Fibre Chemistry 35(2), 128-130.
• 10. Walawska, A., Filipowska, B., Rybicki, E. 2003. Dyeing polyester and cotton-polyester fabrics by means of direct dyestuffs after chitosan treatment. Fibres&Textiles in Eastern Europe 11, 2(41), 71-74.
• 11. Ristić, N., Jovančić, P., Canal, C., Dragan, J. 2009. One-bath One-dye Class Dyeing of PES/Cotton Blends after Corona and Chitosan Treatment. Fibers and Polymers 10(4), 466-475
• 12. Tegegne, W, Tesfaye, T., Zeleke, Y., Ketema, G. 2022. One-bath one-dye class dyeing of polyester/cotton blend fabric with disperse dye after esterification of cotton fabric. Discover Materials. 2:14, https://doi.org/10.1007/s43939-022-00034-2
• 13. Oliveria, FR, Oliveira, D. AJD, Steffens, F., Nascimento, JH, Silva, KKOS, and Souto, AP. 2017. Dyeing of cotton and polyester blended fabric previously cationized with synthetic and natural polyelectrolytes. Procedia Engineering 200, 309–316.
• 14. Hilal, NM, Gomaa, S.H., Elsisi, A.A. 2020. Improving Dyeing Parameters of Polyester/Cotton Blended Fabrics by Caustic Soda, Chitosan, and Their Hybrid. Egyptian Journal of Chemistry Vol. 63, No.6, pp. 2379- 2393.
• 15. Gong, D., Jing, X., Zhao, Y., Zheng, H., Zheng, L. 2021. One-step supercritical CO2 color matching of polyester with dye mixtures. Journal of CO2 Utilization 44, 101396, https://doi.org/10.1016/j.jcou.2020.101396.
• 16. Abidin, T.M.S.T.Z., Ahmad, M.R., Kadir, M.I.A., Yusof, N.J.M., Ahmad, W. Y.W. 2016. Ultrasound Dyeing of Polyester Using Natural Colorant From Melastoma Malabathricum l.Advanced Materials Research 1134, 66-69.
• 17. Enescu, D. 2008. Use of Chitosan in Surface Modification of Textile Materials. Roumanian Biotechnological Letters 13(6), 4037-4048.
• 18. Ibrahim, H., El- Zairy, E.M.R., Emam, E.M., Adel, E. 2019. Combined Antimicrobial Finishing Dyeing Properties of Cotton, Polyester Fabrics and Their Blends with Acid and Disperse Dyes, Egyptian Journal of Chemistry 62(5), 965 – 976.
• 19. Grgac, SF, Tarbuk, A., Dekanic, T., Sujka, W., Draczynski, Z. 2020. The Chitosan Implementation into Cotton and Polyester/Cotton Blend Fabrics. Materials 13, 1616; doi:10.3390/ma13071616
• 20. Manyukova, I. I., Safonov, V. V. 2009. Effect of Chitosan on Dyeing of Chemical Fibres, Fibre Chemistry 41(3), 169-173.
• 21. Zhou, C., Kan, C., Sun, C., Du, J., Xu, C., 2019. A Review of Chitosan Textile Applications. AATCC Journal of Research, 6(1), 8-11.
• 22. Islam, S., Butola, B.S., 2019. Recent advances in chitosan polysaccharide and its derivatives in antimicrobial modification of textile materials. International Journal of Biological Macromolecules 121, 905-912.
• 23. Sancar Beşen, B., Balcı, O. 2017. Investigation of the Effects of Silicone Emulsions HavingDifferent Particle Sizes on Knitted Fabrics Depending on the Type of Yarn, International Journal of Clothing Science and Technology 29(3):394-416.
• 24. Cengiz, Ö.F., Erkale, İ., Özkayalar, S., Alay Aksoy, S., Boyacı, B., Kaplan, S. 2019.Investigation of Transfer and Functional Properties of the Microcapsule Applied Fabrics.Journal of Textiles and Engineer 26(115): 243-251.
• 25. ISO 13938-2:2019: Textiles - Bursting properties of fabrics- Part 2: Pneumatic method for determination of bursting strength and bursting distension.
• 26. TS EN ISO 105-C06: Textiles - Tests for colour fastness - Part C06: Colour Fastness to Domestic and Commercial Laundering
• 27. TS EN ISO 105-E01: Textiles - Tests for colour fastness colour fastness to water
• 28. TS EN ISO 105-E04: Textiles - Tests for colour fastness - Part E04: Colour Fastness to Perspiration
• 29. TS EN ISO 105-X12: Textiles - Tests for colour fastness colour fastness to rubbing
• 30. Miankafshe, MA., Bashir, T., Persson, N., 2019. The role and importance of surface modification of polyester fabrics by chitosan and hexadecylpyridinium chloride for the electrical and electro-thermal performance of graphenemodified smart textiles New J. Chem. 43: 6643-6658.
• 31. Grosicki, Z. J. (2004). Watson's Textile Design and Colour, Woodhead Publishing Limited, Cambridge, England, 368–377.
• 32. Radko Kovar, Yordan Kyosev. (2003). Limit Packing Density of Woven Fabrics, VIII Conference of the Faculty of Power Machines (EMF), of TU Sofia, Bulgaria, 187-192.
• 33. Narkhedkar, R.N., Kane, C.D. 2012, Study of yarn cross-section shape and its diameter, The Indian Textile Journal, 4(6), 36-40.
• 34. Raziye Befru Turan, Ayse Okur. (2012). Variation of the Yarn Cross-Section in Fabric, Textile Research Journal, 82(7), 719-724.
• 35. Behera, B.K., Mishra, R., Militky, J., Kremenakova, D. 2012. Modeling of Woven Fabrics Geometry and Properties, In Han-Yong, J. (Ed.), Woven Fabrics, Intechopen: Croatia, pp. 10-15.
• 36. Sivash Afrashteh, Ali Akbar Merali, Ali Asghar Asgharian Jeddi. (2013). Geometrical Parameters of Yarn Cross-section in Plain Woven Fabric, Indian Journal of Fibre and Textile Research, 38, 126–131.
• 37. Peirce, F. (1937). The geometry of cloth structure. The Journal of the Textile Institute Transactions, 28, T45–T96.
• 38. Wong, C. C., Long, A. C., Sherburn, M., Robitaille, F., Harrison, P., & Rudd, C. D. (2006). Comparisons of novel and efficient approaches for permeability prediction based on the fabric architecture. Composites Part A: Applied Science and Manufacturing, 37, 847–857.
• 39. Zhenrong Zhengab, Xiaoming Zhaoa, Chunhong Wangab & Xiaojun, 2015. Investigation of automated geometry modeling process of woven fabrics based on the yarn structures, The Journal of The Textile Institute, 106 (9), 925–933.
• 40. Afrashteh, S., Merati, A.A., Jeddi, A.A.A. 2013. Geometrical parameters of yarn cross-section in plain woven fabric. Indian Journal of Fibre & Textile Research, 38(2), 126-131.
• 41. Kovar, R., Kyosev, Y. 2004. Limit packing density of woven fabrics, Romanian Textile Journal, 1, 35-42.
• 42. Turan, R.B., Okur, A. 2012. Variation of the yarn cross-section in fabric, Textile Research Journal, 82(7), 719-724.
• 43. Ozgen B and Gong H. 2010. Yarn geometry in woven fabrics. Textile Research Journal, 81, 738–745.
• 44. Behera, B.K., Mishra, R. 2008. 3 – Dimensional Weaving, Indian Journal of Fibre & Textile Research, 33(4), 274–287.
• 45. Bogdanovich, A.E., Mohamed, M.H. 2009. Three-dimensional reinforcements for composites, SAMPE Journal, 45(6), 8-28.
• 46. Khokar, N. 1996. 3D fabric-forming processes: distinguishing between 2D-weaving, 3D-weaving and an unspecified non-interlacing process, Journal of the Textile Institute, 87(1), 97-106.
• 47. Unal, P.G. 2012. 3D woven fabric, In Han-Yong, J. (Ed.), Woven Fabrics, Intechopen, Croatia, 91-120.
• 48. Panneerselvam, R.G., Rathakrishnan, L., Vijayakumar, H.L. 2015. Weaving ‘figured-face flip face-fabric’using orthogonal weft tapestry weave, Indian Journal of Fibre & Textile Research, 40(4), 320–328.