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Enhancement of Hydrostatic Resistance and Mechanical Performance of Waterproof Breathable Laminated Fabrics

Wybrane pełne teksty z tego czasopisma
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Waterproof breathable laminated fabrics have the special property that permits water vapour to pass through but protects by preventing the entrance of liquid water. Different characteristic properties of the layered constructions of these fabrics have good influence on their hydrostatic resistance and mechanical performance. This research study presents an experiment to enhance the hydrostatic resistance and tensile strength of four different types of hydrophobic membrane laminated waterproof fabrics by considering their breathability as well. For this purpose, water repellent coating based on C6-fluorocarbon resin along with polysiloxane hydrophobic softening agent was applied on these four different types of laminated fabrics using pad-dry-cure method. The coated fabrics were characterised by performing different experiments to evaluate the effect of coating on their hydrostatic resistance and mechanical property as well as on water vapour permeability and air permeability. From the test results and analysis of variance (ANOVA), it was found that hydrostatic resistance and tensile strength of the laminated fabrics were enhanced after coating along with proper water repellent property, whereas there were no significant changes in their water vapour permeability and air permeability.
Rocznik
Strony
44--53
Opis fizyczny
Bibliogr. 19 poz.
Twórcy
  • Department of Textile Evaluation, Technical University of Liberec, Studentska 1402/2, Liberec, Czech Republic, araztm29@yahoo.com
  • Department of Textile Evaluation, Technical University of Liberec, Studentska 1402/2, Liberec, Czech Republic
autor
  • Department of Textile Evaluation, Technical University of Liberec, Studentska 1402/2, Liberec, Czech Republic
Bibliografia
  • [1] Ahmad, S., Ahmad, F., Afzal, A., Rasheed, A., Mohsin, M. & Ahmad, N. (2015). Effect of weave structure on thermo-physiological properties of cotton fabrics. AUTEX Research Journal, Vol. 19, No 1, March 2019, 15(1), 30–34.
  • [2] Ahn, H. W., Park, C. H. & Chung, S.E. (2010). Waterproof and breathable properties of nanoweb applied clothing. Textile Research Journal, 81, 1438–1447.
  • [3] Boguslawska-Baczek, M. & Hes, L. (2013). Effective water vapour permeability of wet wool fabric and blended fabrics. Fibers and Textiles in Eastern Europe, 21, 67–71.
  • [4] Chen, Q., Miao, X., Mao, H., Ma, P. & Jiang, G. (2016). The comfort properties of two differential-shrinkage polyester warp knitted fabrics. AUTEX Research Journal, Vol. 19, No 1, March 2019, 16(2), 90-99.
  • [5] Chinta, Dr. S. K. & Satish, D. (2014). Studies in waterproof breathable textiles. International Journal of recent development in engineering and technology, 3, 16–20.
  • [6] Das, B., Das, A., Kothari, V., Fanguiero, R. & Araujo, M. D. (2009). Moisture flow through blended fabrics - effect of hydrophilicity. Journal of Engineered Fibers and Fabrics, 4, 20–28.
  • [7] Fridrichova, L (2013). A new method of measuring the bending rigidity of fabrics and its application to the determination of the their anisotropy. Textile Research Journal, 83, 883–892.
  • [8] Gretton, J. C., Brook, D. B., Dyson, H. M. & Harlock, S. C. (1998). Moisture Vapor transport through waterproof breathable fabric and clothing systems under a temperature gradient. Textile Research Journal, 68, 936–941.
  • [9] Kale, B. M., Wiener, J., Militky, J., Rwawiire, S., Mishra, R., Jacob, K. I. & Wang, Y. (2016). Coating of cellulose-TiO2 nanoparticles on cotton fabric for durable photocatalytic self-cleaning and stiffness. Carbohydrate Polymers, 150, 107–113.
  • [10] Kang, Y. K., Park, C. H., Kim, J. & Kang, T. J. (2007). Application of electrospun polyurethane web to breathable waterproof fabrics. Fibers and Polymers, 8, 564–570.
  • [11] Maqsood, M., Nawab, Y., Shaker, K., Umair, M., Ashraf, M., Baitab, D. M., Hamdani, S.T.A. & Shahid, S. (2016). Modelling the effect of weave structure and fabric thread density on mechanical and comfort properties of woven fabrics. AUTEX Research Journal, Vol. 19, No 1, March 2019, 16(3), 160–164.
  • [12] Mukhopadhyay, A. & Midha, V. (2008). A review on designing the waterproof breathable fabrics. Part-I: Fundamental principles and designing aspects of breathable fabrics. Journal of Industrial Textiles, 37, 225–262.
  • [13] Ozcan, G. (2007). Performance evaluation of water repellent finishes on woven fabric properties. Textile Research Journal, 77, 265–270.
  • [14] Ozen, I. (2012). Multi-layered breathable fabric structures with enhanced water resistance. Journal of Engineered Fibers and Fabrics, 7, 63–69.
  • [15] Save, N. S., Jassal, M. & Agrawal, A. K. (2002). Polyacrylamide based breathable coating for cotton fabric. Journal of Industrial Textiles, 32, 119–138.
  • [16] Wang, J. H. & Yasuda, H. (1991). Dynamic water vapor and heat transport through layered fabrics. Part-I: Effect of surface modification. Textile Research Journal, 61, 10–20.
  • [17] Yadav, A. K., Kasturiya, N. & Mathur, G. N. (2002). Breathability in polymeric coatings. Man-Made Textiles in India, 45, 56–60.
  • [18] Yoon, H. N., Sawyer, L. C. & Buckley, A. (1984). Improved comfort polyester. Part-II: Mechanical and surface properties. Textile Research Journal, 54, 357–365.
  • [19] Zhu, G., Kremenakova, D., Wang, Y. & Militky, J. (2015). Air permeability of polyester nonwoven fabrics. AUTEX Research Journal, Vol. 19, No 1, March 2019, 15(1), 8–12.
Uwagi
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-9c4d58c0-12c2-4f8a-bd63-693677562077
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