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Review. Journal of Surfactants and Detergents, 18(2) 199-204. [4] Parvinzedeh M., Hajiraissi R. (2008). Effect of nano and micro emulsion silicone softeners on properties of polyester fibers. Tenside Surf. Det. 45(5), 254-257. [5] Pathiban M., Kumar M.R. (2007). Effect of fabric softener on thermal comfort of cotton and polyester fabrics. Indian Journal of Fibre & Textile Research, 32, 446-452. [6] Montazer M., Hashemikia S. (2012). Application of polyurethane/citric acid/silicone softener composite on cotton/polyester knitted fabric producing durable soft and smooth

multifunctional coatings for cotton fabrics. Thin Solid Films, 520(14), 4658-4661. [8] Ashraf, M., Champagne, P., Perwuelz, A., Campagne, C., Leriche, A. (2014). Photocatalytic solution discoloration and self-cleaning by polyester fabric functionalized with ZnO nanorods. Journal of Industrial Textiles, 44, 1-15. [9] Baghriche, O., Rtimi, S., Pulgarin, C., Roussel, C., Kiwi, J. (2013). RF-plasma pretreatment of surfaces leading to TiO2 coatings with improved optical absorption and OHradical production. Applied Catalysis B: Environmental, 130–131, 65-72. [10] Ashraf, M

References [1] Hezavehi, E., Shahidi, S., Zolgharnein, P. (2015). Effect of dyeing on wrinkle properties of cotton cross-linked by Butane Tetracarboxylic Acid (BTCA) in presence of Titanium Dioxide (TiO 2 ) Nanoparticles. Autex Research Journal, 15(2), 104-111. [2] Jafari-Kiyan, A., Karimi, L., Davodiroknabadi, A. (2017). Producing colored cotton fabrics with functional properties by combining silver nanoparticles with nano titanium dioxide. Cellulose, 24(7), 3083-3094. [3] Ayazi-Yazdi, S., Karimi, L., Mirjalili, M., Karimnejad, M. (2017). Fabrication of

References 1. Kandola, B.K., Horrocks, A.R., Price, D. & Coleman G.V. (2006). Flame retardant treatments of cellulose and their influence on the mechanism of cellulose pyrolysis. J. Macromol. Sci., 36(4), 721-794. DOI: 10.1080/15321799608014859. 2. Charuchinda, S., Srikulkit, K. & Mowattana, T. (2005). Coapplication of sodium polyphosphateand chitosan to improve flame retardancy of cotton fabric. J. Sci. Res. Chula. Univ., 30 (1), 97-110. DOI: 10.1177/0734904112443658. 3. Horrocks, A.R. (2011). Flame retardant challanges for textiles and fibres. Polym. Degrad

thermal resistance of polyester/cotton blended interlock knitted fabrics. In: International Journal of Thermal Sciences, 2014, vol. 85, pp. 40-46 [8] Cimilli, S., Nergis, B. U. and Candan, C. A comparative study of some comfort related properties of socks of different fiber types. In: Textile Research Journal, 2010, vol. 80, issue 10, pp. 948-957 [9] Schneider, A. M., Hoschke, B. N. and Goldsmid, H. J. Heat transfer through moist fabrics. In: Textile Research Journal, 1992, vol. 62, issue 2, pp. 61-66 [10] Wan, X., Fan, J. and Wu, H. Measurement of thermal radiation

properties of denim fabrics produced from these yarns. The effect of linear density, twist multiplier, stretch percentage, and applied load on tenacity and elastic performance of cotton/Lycra core-spun denim yarn was investigated [ 1 ]. Due to its lower linear density, stretch, and twist multiplier, the cotton/Lycra core-spun yarn has better elastic performance. The weight, size, elasticity, tensile strength, and cost properties of the denim fabrics woven with the dual-core weft yarn with different densities were evaluated [ 2 ]. In stretched knitted fabric, the additional

References [1] Prakash, C., G. Ramakrishnan, and C. Koushik, Effect of blend ratio on the quality characteristics of bamboo/cotton blended ring spun yarn. Fibres & Textiles in Eastern Europe, 2011. 19(6): p. 38-40. [2] Özdil, N., A. Marmaralı, and S.D. Kretzschmar, Effect of yarn properties on thermal comfort of knitted fabrics. International journal of Thermal sciences, 2007. 46(12): p. 1318-1322. [3] Islam, N., Environmental issues in Bangladesh: an overview. Pakistan journal of social sciences, 2005. 3(4): p. 671-679. [4] Qureshi, A.S., Climate change and

References [1] Matusiak M.: Thermal Insulation of Woven Fabric for Clothing. Monograph, Works of Textile Research Institute, Special Edition, Lodz 2011, ISBN 978-83-911544-7-2. [2] [3] Andrysiak J., Sikorski K., Wilk E., Matusiak M., Investigation of an Innovative “Cotton Hollow” Yarn, FIBRES & TEXTILES in Eastern Europe 2014; 22, 5(107), pp. 33-37. [4] Unal P.G., 3D Woven Fabrics, chapter in: Woven Fabrics edited by Han-Yong Jeon, In -Tech Croatia 2012, ISBN 978-953-51-0607-4, pp. 91-120 [5] Chen X

-Hammed M., Adeoye D. O., 2014, Effect of modifying agents on percentage equilibrium exhaustion of an acid dye on nylon fabric Australian J. Basic Appl. Sci. 8 (1), 552-559 El-Molla, M., Badawy, N., AbdEl-Aal, A., El-Bayaa, A., El-Shaimaa, H., 2011, Dyeability of cationised cotton and nylon 6 fabrics using acid dyes. Fang, L., Zhang, X., Ma, J., Sun, D., Zhang, B., Luan, J., 2015, Ecofriendly cationic modification of cotton fabrics for improving utilization of reactive dyes. RSC Advances 5, 45654-45661. Fang, L., Zhang, X., Sun, D., 2013, Chemical modification of cotton

Clothing, ed: Springer, 2014, pp. 239-276. [7] Kilic, M. and Okur, A. (2011). The properties of cotton-Tencel and cotton-Promodal blended yarns spun in different spinning systems, Textile Research Journal, 81(2). 156-172. [8] Xijun, W.H.Y. (2007). Development of Tencel Fiber Pure Yarn and Tencel Blended yarn [J], Cotton Textile Technology, 10(p020. [9] Firgo, H., Suchomel, F. and Burrow, T. (2006). Tencel® high performance sportswear, Lenzinger Berichte, 85(44-50. [10] Shanmugasundaram, G.K.G.N.O. (2016). Thermal comfort properties of bamboo tencel knitted fabrics