Nanocoat Finishing of Polyester/Cotton Fabrics by the Sol-Gel Method to Improve their Wear Resistance

Brzeziński, S.; Kowalczyk, D.; Borak, B.; Jasiorski, M.; Tracz, A.

Artykuł - szczegóły

Tytuł artykułu

Nanocoat Finishing of Polyester/Cotton Fabrics by the Sol-Gel Method to Improve their Wear Resistance

Autorzy

Brzeziński S. , Kowalczyk D. , Borak B. , Jasiorski M. , Tracz A.

Wybrane pełne teksty z tego czasopisma

Identyfikatory

Warianty tytułu

Wykończenie nanopowłokowe metodą zol-żel zwiększające trwałość użytkową tkanin poliestrowo-bawełnianychends

Języki publikacji

Abstrakty

A serious drawback of the commonly used textiles of polyester/cotton fibres blends (PET/CO), especially those containing worse cotton brands, is their great susceptibility to form pilling, which adversely affects their performance durability and aesthetic values. Among the many methods of preventing this phenomenon, the thin-coating finishing performed by sol-gel methods provides interesting possibilities in this field. By a proper selection of precursors and synthesis method as well as the deposition of sols, it is possible to form xerogel coats on the fibre surface characterised by considerable hardness and abrasion resistance, thus reducing the formation of pilling, without any deterioration in the aesthetic values of textiles. Moreover, these coatings are strongly combined with the fibre surface and are resistant to the conditions of use and care, including multiple washing processes. The thin-coat finishing of this type also increases the abrasion resistance of textiles with a dominating content of polyester fibres, and thus it positively influences the performance value of textile fabrics. This paper presents the test results of using the hybrid modified SiO2/Al2O3 sol developed, synthesised with the use of two precursors: (3-glycidoxypropyl) trimethoxysilane (GPTMS) and aluminium isopropoxide (ALIPO), and the conditions of its application to the thin-coat finishing of PET/CO (67:33) woven fabrics were selected to increase their abrasion resistance and prevent the formation of pilling. Consequently, the fabric susceptibility to form pilling was practically completely eliminated (assessment at level 5 according to the Martindale test), and the fabric abrasion resistance was increased by 38%, with the effects obtained being resistant to prolonged laundering.

Istotną wadą tekstyliów z mieszanek włókien poliestrowych i bawełnianych jest ich duża skłonność do tworzenia pillingu, co negatywnie wpływa na trwałość użytkową oraz cechy estetyczne wyrobów. Wśród wielu sposobów przeciwdziałania tej skłonności, duże możliwości stwarza wykończenia nanopowłokowe metodą zol-żel. W rezultacie prowadzonych badań ustalono, że w wyniku odpowiedniego doboru prekursorów i addytywów oraz opracowanych metod syntezy, a następnie włókienniczej aplikacji zoli, można wytwarzać na powierzchniach włókien cienkie powłoki kserożelowe, które nie powodując pogorszenia cech estetycznych tekstyliów, jednocześnie istotnie zwiększają odporność tkanin na ścieranie, a więc i mechacenie, a w rezultacie na tworzenie pillingu. Powłoki takie są silnie związane z powierzchniami włókien i odporne na warunki użytkowania i konserwacji wyrobów, w tym wielokrotne prani

Słowa kluczowe

textile fabric PET/cotton blends sol-gel coating thin-coat finishing hybride modified sol xerogel performance durability of textiles abrasion resistance pilling

mieszanki PET / bawełna powłoka zol-żel wykończenie cienki płaszcz hybrydowy-zol kserożel modyfikowany trwałość wykonania tekstyliów odporność na ścieranie pilling

Wydawca

Sieć Badawcza Łukasiewicz - Łódzki Instytut Technologiczny

Czasopismo

Fibres & Textiles in Eastern Europe

Rocznik

2011

Tom

Vol. 19, no. 6 (89)

Strony

83--88

Opis fizyczny

Bibliogr. 29 poz., rys.

Twórcy

autor

Brzeziński S.

s.brzezinski@iw.lodz.pl

Poland, Łódź, Textile Research Institute, Department of Non-conventional Techniques and Textiles

autor

Kowalczyk D.

Poland, Łódź, Textile Research Institute, Department of Non-conventional Techniques and Textiles

autor

Borak B.

Poland, Wrocław, Wrocław University of Technology, Institute of Materials Science and Applied Mechanics

autor

Jasiorski M.

Poland, Wrocław, Wrocław University of Technology, Institute of Materials Science and Applied Mechanics

autor

Tracz A.

Poland, Łódź, Centre of Molecular and Macromolecular Studies – Polish Academy of Sciences

Bibliografia

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28. Standard PN-EN ISO 6330:2002. “Textiles. Domestic Washing and Drying Procedure for Textile Testing. Procedure 5A (40 °C)”.
29. Polish Patent Application No P-395765, 2011; Brzeziński S., Kowalczyk D., Malinowska G., Kaleta A., Jasiorski M., Borak B., Baszczuk A.; Production methode of textile materials with increased usage durability.

Typ dokumentu

Bibliografia

Identyfikator YADDA

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