Seyda Canbolat, Nigar Merdan, Dilek Kut

9095

INVESTIGATION OF THE EFFECT OF THE DYEING METHOD ON THE DYEING PROPERTIES OF SILK FABRIC DYED WITH NATURAL DYE

INVESTIGATION OF THE EFFECT OF THE DYEING METHOD ON THE DYEING PROPERTIES OF SILK FABRIC DYED WITH NATURAL DYE

In this study, silk fabric was dyed with the natural dye extracted from blueberry (Vaccinium corymbosum L.) via ultrasonic, microwave and conventional methods. One of the samples dyed via conventional method was treated oxygen plasma treatment whereas the other was mordanted with aluminium potassium sulphate prior to the dyeing process. The colour and fastness properties of the dyed fabrics were investigated and compared with each other in terms of dyeing method. The physical structure of samples was analysed with scanning electron microscope (SEM). The chemical structure of samples was characterized by Fourier transform infrared spectroscopy (FTIR ATR). According to the results, the samples dyed via microwave method had the best results in terms of colour properties. Furthermore, when compared with one another in terms of dyeing methods, there were no significant differences between fastness properties of dyed samples.
Keywords:

Vaccinium Corymbosum L., Ultrasonic Method, Microwave Method Conventional Method, Plasma Treatment, Fastness Properties,

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  • Bulut M.O., Akar E. Ecological dyeing with some plant puls on woollen yarn and cationized cotton fabric, Journal of Cleaner Production 2012; 32; 1-9.
  • Angelini L.G., Bertoli A., Rolandelli S., Pistelli L. Agronomic potential of Reseda luteola L. as new crop for natural dyes in textiles production, Industrial Crops and Products 2003; 17; 199-207.
  • Ibrahim N.A., El-Gamal G.M., Mahrousa F. A new approach for natural dyeing and functional finishing of cotton cellulose, Carbohydrate Polymers 2010; 82; 1205– 1211.
  • Bechtold T., Amalid M.A., Mussak R. Natural dyes in modern textile dyehouses — How to combine experiences of two centuries to meet the demands of the future?, Dyes and Pigments 2007; 75; 287-293.
  • Haar S, Schrader E, Gatewood B.M. Comparison of aluminum mordants on the colorfastness of natural dyes on cotton, Clothing and Textiles Research Journal 2013; 31(2); 97-108.
  • Barka N, Assabbane A, Nounah A, Laanab L, Ichou Y.L. Removal textile dyes from aqueous solution by natural phosphate Desalination 2009; 235; 264–275.
  • Baliarsingh S, Panda A.K, Jena J, Das T,
  • Das N.B. Exploring sustainable technique on natural dye extraction from native plants for textile: identification of colourants, colourimetric analysis of dyed yarns and their antimicrobial evaluation, Journal of Cleaner Production 2012; 37; 257-264.
  • Shanker R, Vankar P.S. Dyeing cotton, wool and silk with< i> Hibiscus mutabilis(Gulzuba), Pigments 2007; 74; 464-469. Dyes and
  • Kale K.H, Palaskar S. Atmospheric pressure plasma
  • polymerisation of hexamethyldisiloxane for imparting water repellency to cotton fabric, Textile Research Journal 2011; 81(6); 608–620.
  • Verschuren, J., Herzele, P.V., Clerck, K.D., Kıekens, P. Influence of fiber surface purity on wicking properties of needle- punched nonwoven after oxygen plasma treatment, Textile Research Journal 2005; 75(5); 437–441.
  • Sahahidi S, Rashidi A, Ghoranneviss M, Anvari A. Wiener, J. Influence of plasma sputtering treatment on natural dyeing and antibacterial activity of wool fabrics, Surface&Coatings Technology 2010; 205; 349-354.
  • Omerogulları Z, Kut D. Application of low-frequency oxygen plasma treatment to polyester fabric to reduce the amount of flame retardant agent, Textile Research Journal 2012; 82(6); 613–621.
  • Bhat N.V, Netravali A.N, Gore A.V, Sathianarayanan Deshmukh R.R. Surface modification of cotton fabrics using plasma Technology, Textile Research Journal 2011; 81(10); 1014–1026. Arolkar G.A,
  • Mason T.J, Lormier J.P. Uses of ultrasonic chemistry, Ellis Horwood Limited; 1988.
  • Khatri Z, Memonb M.H, Khatri A, Tanwari A. Cold Pad-Batch dyeing method for cotton fabric dyeing with reactive dyes using ultrasonic energy, Ultrasonics Sonochemistry 2011; 18; 1301–1307.
  • Büyükakıncı, B.Y, Usage of Microwave Energy in Turkish Textile Production Sector, Energy Procedia 2012; 14; 424 – 431.
  • Ahmed N. S. E, El-Shishtawy R.M.E. The use of new technologies in coloration of textiles fibers, Journal of Materials Science 2010; 45(5); 1143-1153.
  • Wang S.Y, Chen C.T. Effect of allyl isothiocyanate on antioxidant enzyme activities, flavonoids and post-harvest fruit quality corymbosum L., cv. Duke), Food Chemistry 2010; 122; 1153–1158.
  • Punrattanasin N, Nakpathom M, Somboon B, Narumol N, Rungruangkitkrai N, Mongkholrattanasit R. Silk fabric dyeing with natural dye from mangrove bark (Rhizophora apiculata Blume) extract Ind.Crops and Products 2013; 49; 122-129.
  • Lin Y. H, Saotome A, Kohno Y, Shibata M. Antrahocyanidin dye and Al/Fe-containing mesoporous silica composites and their color properties, Journal of the Japan Society of Colour Material 2013; 86(11); 397-402.
  • ISO 105-C06 Standard. Textiles-Tests for Colour Fastness- Part C06: Colour Fastness to Domestic and Commercial Laundering, (2010).
  • EN ISO 105 – B02 Standard. Textiles-Tests for Colour Fastness- Part B02: Colour Fastness to Artificial Light: Xenon Acr Fading Lamp Test, (1994).
  • ISO 105 X12 Standard. Textiles-Tests for Colour Fastness- Part X12: Colour Fastness to Rubbing, (2001).
  • Oner E, Büyükakıncı Y, Sökmen N. Microwave-assisted poly(butylene terephthalate) fabrics with disperse dyes, Coloration Technology 2013; 129; 125-130. dyeing of
  • Duran K ,Bahtiyari M.İ, Körlü A.E, Dereli S. Ultrasonic technology, Tekstil ve Konfeksiyon 2006, 3, 155.
  • Gogate, P.R. Cavitational reactors for
  • intensification process
  • processing applications: a critical review,
  • Chemical Engineering and Processing:
  • Process Intensification 2008; 47 (4); 515- 527. [27] Guesmi of chemical A, Ladhari
  • Ultrasonic preparation of cationic cotton
  • and its application in ultrasonic natural
  • dyeing, Ultrasonics Sonochemistry 2013; 20; 571–579. N, Sakli F,
  • Akalin M, Merdan N, Kocak D, Usta I. Effects of ultrasonic energy on the wash fastness of reactive dyes, Ultrasonics 2004; 42; 1–9.
  • Arai T, Freddi G., Innocenti R, Tsukada M. Biodegradation of Bombyx mori silk fibroin fibers and films, Journal of Applied Polymer Science 2004; 91 (4); 2383–2390.
  • Shao, J., Zheng, J., Liu, J., Carr, C.M. Fourier transform Raman and Fourier transform infrared spectroscopy studies of silk fibroin, Journal of Applied Polymer Science 2005; 96 (6); 1999-2004.
  • Mathur A.B, Tonelli A, Rathke T, Hudson S. The dissolution and characterization of
  • Bombyx mori silk fibroin in calcium nitrate‐ methanol
  • regeneration of films, Biopolymers 1997;
  • (1); 61–74. and the
International Journal of Electronics Mechanical and Mechatronics Engineering-Cover
  • ISSN: 2146-0604
  • Başlangıç: 2011
  • Yayıncı: İstanbul Aydın Üniversitesi
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