Pigment baskı patı ile basılmış nano boyutta gümüş/çinko partiküllerin renk performası üzerine etkisi

Bu çalışmada, pigment baskı patına nano boyutta gümüş/çinko metal formunda partikül eklenerek fonksiyonel kumaş elde edilmeye çalışılmıştır. Baskı aşamasında nano boyutta gümüş ve çinko karıştırılmış pat, pamuklu kumaş üzerine el şablonu tekniği ile basılmıştır. Elektron mikroskobu ve enerji dağılım X ışını (EDX) tekniği ile pigment baskı yüzeyinde nano metal partiküller belirlenmiştir. İşlemli kumaşların renk özelliklerine ait; CIE L* a* b* renk koordinatları, K/S renk gücü ve sürtme haslığı incelenmiştir. Pigment baskılı kumaşların yüzeyinde oluşan nano metal partiküllerin renk üzerine etkisi incelendiğinde; renk koordinatlarını değiştirdiği, ve sürtme haslığını düşürdüğü görülmüştür. Baskılı kumaşların antibakteriyel fonsiyonel özelliği bir sonraki çalışmada değerlendirilecektir

Effect of nano-sized silver/zinc particles in pigment printing paste on color performance

In this study, it is aimed to obtain functional fabric by adding nano-sized silver/zinc metal basis particle into pigment printing paste. At the stage of printing, nano-sized silver and zinc were mixed and the paste was printed by hand screen technique on cotton fabric. The nano metal particles on the surface of pigment printing were determined with electron microscopy and energy dispersive X-ray technique (EDX). The color properties of treated fabrics; CIE L * a * b * color coordinates, K/S color strength and rubbing fastness were investigated. When the effect of nano metal particles on the surface of printed fabrics was examined it was found that the color coordinates has changed and rubbing fastness has decreased. Antibacterial functional properties of the printed fabric will be determined in future studies.

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  • 1. Miles, L.W.C., (1994), Textile Printing, Society of Dyers and Colurists, West Yorkshire, 15.
  • 2. Wang, C.X., Yin, Y.J., Wang, X.X., Bu, G.J., (2008), Improving the Color Yield of Ultra-fine Pigment Printing on Cotton Fabric, AATCC Review, 8(2), 41-45.
  • 3. Ibrahim, N.A., Refaire, R, Ahmed E.F., (2010), Nowel Approach for Attaining Cotton Fabric with Multi-Functional Properties, Journal of Industrial Textiles, 40(1), 49-64.
  • 4. Jocic D, Tourrette, A, Glampedaki, P, Warmoeskerken, (2009), Application of temperature and pH responsive microhydrogels for functional finishing of cotton fabric, Materials Technology, 24(1), 14-23.
  • 5. Gulrajani, ML, Gupta, D, 2011, Emerging techniques for functional finishing of textile, Indian Journal of Fibre & Textile Research, 36(4), 288-397.
  • 6. Ilic, V., Sapnjic, Z., Vodnik, V., (2009), The Influence of Silver Content on Antimicrobial Activity and Color of Cotton Fabrics Functionalized wit Ag Nanoparticles, Carbohydrate Polymers, 78, 564-569
  • 7. Hipler, U.C., (2008), Textiles with Antimycotic and Antibacterial Properties, Mycoses, 51, 39-43.
  • 8. Gasti M.P., Alimohammadi F., Shamei, A, (2012), Preparation of water-repellent cellulose fibers using a polycarboxylic acid/hydrophobic silica nanocomposite coating, Surface & Coatings Technology, 206(14), 3208-321.
  • 9. Liu, J.Q., Shao, J.Z., Wang, G.M., Lu, S.F., Fan, Q.G., (2007), Effect of wool surface modification on water repel- lent and oil repellent finishings, Acta Polymerica, 1, 75-80
  • 10. Hebeish, A.; El-Naggar, M. E.; Fouda, Moustafa M. G., (2011), Highly effective antibacterial textiles containing green synthesized silver nanoparticles, Carbohydrate Poly- mers, 86 (2), 936-940.
  • 11. Kurajica, S., Ocko, T., Mandic, (2012), Properties and An- timicrobial Activity of Nanosilver Deposited Cotton Fabric Coated with gamma-methacryloxypropyl Trimethoxysilane, Journal of Nano Research, 20, 77-88.
  • 12. Montazer, M., Alimohammadi, F., Shamei, A., (2012), In situ synthesis of nano silver on cotton using Tollens' reagent, Carbohydrate Polymers, 87 (2), 1706-1712.
  • 13. Zhang, D.S., Toh, G.W., Lin, H., Chen, Y.Y., (2012), In situ synthesis of silver nanoparticles on silk fabric with PNP for antibacterial finishing, Journal of Materials Science, 47(15), 5721-5728.
  • 14. Tang, B., Wang, J.F., Xu, S.P., Afrin, T., Tao, J.L., Xu, W.Q., Sun, L., Wang, X.G., (2012), Function improvement of wool fabric based on surface assembly of silica and silver nanoparticles, Chemical Engineering Journal, 185, 366-373.
  • 15. Gawish, S.M., Avci, H., Ramadan, A.M., Mosleh, S., Monti- cello, R., Breidt, F., Kotek, R., (2012), Properties of Antibac- terial Polypropylene/Nanometal Composite Fibers, Journal of Biomaterials Science-Polymer, 23(1-4), 43-61.
  • 16. Moosavi, R., Abbasi, A.R., Yousefi, M., Ramazani, A., Mor- sali, A., (2012), Ultrasoundassisted coating of polyester fiber with silver bromide nanoparticles, Ultrasonics Sonochemis- try, 19(6), 1221-1226.
  • 17. Bilget, Ö., (2013), Nano Boyutta Gümüş/Çinko Katkılı Pigment Baskı Uygulanmış Kumaşların Antibakteriyel Özelliklerinin Araştırılması, Erciyes Üniversitesi Fen Bilimleri Enstitüsü, Yüksek Lisans Tezi, Kayseri.