Narzędzia help

Preferencje help
Widoczny [Schowaj] Abstrakt
Liczba wyników
cannonical link button

http://yadda.icm.edu.pl:80/baztech/element/bwmeta1.element.baztech-7df46389-7289-4ecd-8c3d-d2d77b117011

Czasopismo

Fibres & Textiles in Eastern Europe

Tytuł artykułu

Effect of Weave Structures and Zinc Oxide Nanoparticles on the Ultraviolet Protection of Cotton Fabrics

Autorzy Timothy, R.  Arul Pragasam, A. J. 
Treść / Zawartość
Warianty tytułu
PL Wpływ struktur splotów i nanocząstek tlenku cynku na ochronę UV tkanin bawełnianych
Języki publikacji EN
Abstrakty
EN The protection provided by clothing against ultraviolet (UV) radiation has been the subject of considerable recent research. However, there is a lack of information concerned with the effect of weave structures and zinc oxide nanoparticles on these properties. A series of cotton fabrics differing in weave structure was produced and treated with zinc oxide nanoparticles. These fabrics were spectrophotometrically assessed and the UV protection factor calculated. It was found that while there was no significant difference in the Ultraviolet Protection Factor (UPF) in untreated samples, in samples treated with zinc oxide nanoparticles an increase was noticed in satin and granite weaves. There is no relationship between weave parameters and the UPF. Also between porosity and the UPF, no relationship was noticed. Thus the present study provides design guidelines for clothing manufacturers.
PL Ochrona zapewniana przez odzież przed promieniowaniem ultrafioletowym (UV) była przedmiotem wielu badań. Brak jest jednak informacji dotyczących wpływu struktur splotów i nanocząstek tlenku cynku na te właściwości. Przedmiotem pracy było wytworzenie tkanin bawełnianych różniących się strukturą splotów, a następnie poddano te tkaniny obróbce nanocząstkami tlenku cynku. Tkaniny te zostały ocenione spektrofotometrycznie i obliczono współczynnik ochrony przed promieniowaniem UV. Stwierdzono, że chociaż nie było istotnej różnicy we współczynniku ochrony przed promieniowaniem ultrafioletowym (UPF) w nieobrabianych próbkach, w próbkach obrabianych nanocząsteczkami tlenku cynku zauważono wzrost w splocie satynowym i granitowym. Stwierdzono, że nie ma związku pomiędzy parametrami splotu a UPF. Również między porowatością a UPF nie zauważono żadnego związku. Przedstawione wyniki badań mogą być źródłem wytycznych projektowych dla producentów odzieży.
Słowa kluczowe
PL UPF   promieniowanie ultrafioletowe   spektrofotometria   współczynnik tkania   nanocząsteczki tlenku cynku  
EN UPF   spectrophotometric   weave factor   zinc oxide nanoparticles  
Wydawca Instytut Biopolimerów i Włókien Chemicznych
Czasopismo Fibres & Textiles in Eastern Europe
Rocznik 2018
Tom Nr 1 (127)
Strony 113--119
Opis fizyczny Bibliogr. 42 poz., rys., tab.
Twórcy
autor Timothy, R.
autor Arul Pragasam, A. J.
  • Department of Physics, Satyabama University, Rajiv Gandhi Salai, Sholinganallur, Chennai 600119, India
Bibliografia
1. Reichrath J. Ultraviolet damage DNA repair and vitamin D in non melanoma skin cancer and in malignant melanonma an update. AdvExp Med Biol 2014; 810: 208-233.
2. Wilson CA, Parisi AV. Protection from solar erythemal ultraviolet radiation – simulated wear and laboratory testing. Textile Res. J. 2006; 76, 3: 216-225.
3. Vanicek K, Frei T, Litynska Z, Schmalwieser A. COST-713 ACTION, Brussels. 1999.
4. G.Wyszecki and W.S.Stiles Color Science – Concepts and Methods, Quantitative data and formulae, Wiley.
5. Saravanan D. UV protection textile materials. AUTEX Research Journal 2007; 7, 1: 53-59.
6. Beccnir MA, Alpay HR. Ultraviolet (UV) protection of textiles. A Review. International Scientific Conference, 19-26 November 2010, Gabrana.
7. Hussain A, Jahan S. Textiles Protection against Ultraviolet radiation. The Indian Textile Journal. 2010; June.
8. Kathirvelu S, D’Souza, Durai B. UV-protection finishing of textiles using ZnOnanoparticles. Ind. J. Text. Res. 2009; 34: 267-273.
9. Yadav A, Prasad V, Kathe AA, Raj S, Yadav D, Sundaramoorthy C, Vigneswaran N. Functional finishing in cotton fabrics using zinc oxide nano particles. Bull. Mater. Sci. 2006; 29: 641- 645.
10. Stankovic SB, Popovic D, Paparic GB, Bizjak M. Ultraviolet protection factor of gray state pure cotton knitted fabrics. Textile Res. J. 2009; 79, 11: 1034-1042.
11. Wong WY, Lam JKC, Kan CW, Postle R. Impacts of yarn twist and staple length on UV protection of plain-knitted cotton fabrics. JTI 2016; 107.
12. Dubrovski PD, Golob D. Effects of woven fabric construction and colour on Ultraviolet protection. Textile Res. J 2009; 79, 4: 351-359.
13. Grancaric AM, Tarbuk A, Dumitrescu L, Biscon J. UV protection of pretreated cottoninfluence of fwa’s fluorescence. AATCC Review (1532-8813) 2006; 6, 4: 40-46.
14. Dubrovski PD, Brezocnik M. Prediction of the ultraviolet protection of cotton woven fabric dyed with reactive dyes. Fibres & Textiles in Eastern Europe 2009; 17, 1(72): 55-59.
15. Gambichler T, Avermaete A, Bader A, Aetmeyer P, Hoffman K. Ultra violet transmission measurements verified by determination of the minimal erythema dose with solar simulated radiation. Br. J. Dermatol, 2001; 144: 484-489.
16. Paya TC, Diaz-Garcia P, I.Montava, Miro-Martinez, M. Bonet. A new development for determining the ultraviolet protection factor. J. Ind. Textiles, 2014, pp.1-16.
17. Gorensek M, Sluga F. Modifying the UV blocking of polyester fabric. Textile Res. J. 2004; 74, 6: 469-474.
18. Xin JH, Daoud WA, Kong YY. A new approach to UV-blocking treatment for cotton fabrics. Textile Res. J. 2004; 74, 2: 97-100.
19. Yang H, Zhu S, Pan N. Studying the mechanisms of Titanium dioxide as Ultraviolet blocking additive for films and fabrics by an improved scheme. Journal of Applied Polymer Science 2004; 92: 3201-3210.
20. Hustvedt G, Cox Crews P. The ultraviolet protection factor of naturally – pigmented cottons. J. Cotton Sci. 2005; 9: 47-55.
21. Taghipoor F, Hasani H, Khalili H. Structural Parameters effect on UVR transmission of weft knitted fabrics. Indian Journal of Fibre & Textile Research 2015; 40:386-391.
22. Wong WY. Ultraviolet protection of knitwear fabrics, Ph.D. Thesis, The Hong Kong Polytechnic University, Hong Kong, 2014.
23. Kan CW. A study on ultraviolet protection of 100% cotton knitted fabric effect of fabric parameters. The Scientific World Journal 2014; 1-10.
24. Wong WY, Lam JKC, Kan CW, Postle R. Ultraviolet protection of weft knitted fabrics. Textile Progress 2016; 48.
25. FEI WT. Investigation of ultraviolet protective light weight knit wear fabric with direct dyes and optical whitening agents B.A. (Hons) in Fashion and Textiles Institute of Hong Kong Polytechnic University, 2012.
26. Au Chui Ha. Investigation of ultra violet protective cotton knit wear fabric with chemical approach. M.Phil. Thesis, The Hong Kong Polytechnic University, 2013.
27. Marino H, Matsudaira MV, Furutani M. Predictiong Mechanical Properties and hand values from parameters of weave structure. Textile Research Journal 2005; 75, 3: 252257.
28. Milasius V. An integrated structure factor for woven fabrics. Part II The fabric firmness factor. Journal of the textile institute 2000; 106, 7: 736-747.
29. Sankaran V, Subramaniam V. Effect of weave structures on the low stress mechanical properties of woven cotton fabrics. Fibres & Textiles in Eastern Europe 2012; 20, 5: 56-59.
30. Gambichler T, Hatch KL, Avermaete A, Bader A, Herde M, Altmeyer P, Hoffman K. Ultraviolet protection factor of fabrics: Comparison of laboratory and field based measurements. Photodermatol Photo immunol. 10.1007/978-3-642-59410-68.
31. Gambichler T, Hatch KL, Avermaete A, Altmeyer P, Hoffmann K. Influence of wetness on the ultraviolet protection factor (UPF) of textiles. in vitro and in vivo measurements 2002; 18, 1: 29-35.
32. Gambichler T, Rotterdam S, Aetmeyer P, Hoffmann K. Protection against ultraviolet radiation by commercial summer clothing: need for standardized testing and labelling. BMC Dermat 2001; 1: 6.
33. Majumdar A, Kothari VK, Mandal AK, Hatua P. Effect of weave structural parameters and ultraviolet absorbers on in vitro protection factor of bleached cotton woven fabrics. Photodermatol Photoimmunol Photomed 2012; 2: 58-67.
34. Vigneshwaran N, Kumar A, Kathe A, Varadarajan PV, Pradad V. Functional finishing of cotton fabrics using zinc-oxide-soluble starch nano composites. Nanotechnology 2006; 17, 20: 5087-5095.
35. Jazbec K, Sala M, Mozetic M, Vesel A, Gorjanc M. Functionalisation of cellulose fibres with oxygen plasma and ZnO nanoparticles for achieving UV protective properties. Journal of Nanomaterials 2015; 1-9. Article ID 346739.
36. Majumdar A, Kothari VK, Mondal AK. Engineering of cotton fabrics for maximizing in vitro ultraviolet indication protection. Photodermatol, Photoimmunol Photomed. 2010; 26, 6: 290-296.
37. Dubrovski PD. Woven fabrics and ultraviolet protection. In: Dubrovski, P.D.; ed. Woven Fabric Engineering; Sciyo, India, 2010, pp.273-296.
38. Hatna P, Majumdar A, Das A. Modeling ultraviolet protection factor of polyestercotton blended woven fabrics using soft computing approaches. Journal of Engineered Fibres and Fabrics 2014; 9, 3: 99-106.
39. Hatua P, Majumdar A, Das A. Comparative analysis of in vitro ultraviolet radiation protection of fabrics woven from cotton and bamboo viscose yarns. Journal of the Textile Institute 2013; 104, 7: 708-714.
40. Majumdar A, Das A, Hatua P. Ultraviolet radiation protection by cotton fabrics: role of porous yarn structure fabric thickness and pore size. Journal of the Textile Institute 2016; 107, 9: 1159-1168.
41. Upasani PS, Sreekumar TV, Jain A. Polyester fabric with inherent antibacterial hydrophilic and UV protection properties. The Journal of the Textile Institute 2015; 106: 1135-1143.
42. Milasius A, Milasius V, New Representation of the fabric weave factor. FIBRES & TEXTILES in Eastern Europe 2008; 16, 4(69): 48-51
Uwagi
PL Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).
Kolekcja BazTech
Identyfikator YADDA bwmeta1.element.baztech-7df46389-7289-4ecd-8c3d-d2d77b117011
Identyfikatory
DOI 10.5604/01.3001.0010.7806