Indian Journal of Fibre & Textile Research

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Heat-Setting Parameters Optimisation of Cotton/Elastane Fabric Using Response Surface Methodology


Affiliations
1 Department of Mechanical Engineering Technology, Faculty of Engineering Technology, Universiti Tun Hussein Onn Malaysia, 84600 Pagoh, Muar, Johor, Malaysia
2 School of Fashion and Textiles, RMIT University, Melbourne, Australia
 

The effect of heat-setting treatment on the performance of cotton/elastane fabric has been studied. Response surface methodology has been used to design the experiments where temperature (°C), time (s) and fabric width extension (%) are taken as factor variables. Fabric dimension (lengthwise and widthwise), fabric areal density and fabric tension decay are taken as response variables. The findings establish that the optimum heat-setting parameters are 190℃ temperature, 75s process time and 13.5% width extension. It is necessary to optimise the heat-setting parameters to achieve better fabric dimensional stability, as overheating damages and deteriorates some of the elastane filaments, resulting in reduced recovery properties after a certain temperature point.

Keywords

Cotton/Elastane Fabric, Dimensional Stability, Elastane, Heat-Setting Treatment, Knitted Fabric, Single Jersey Fabric, Tension Decay.
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  • Yousuf A, Anwarul M, Sowrov K & Ahmed M, Int J Text Sci, 3(1) (2014) 12.

  • Sitotaw D B, J Text Apparel, Technol Management , 11(2) (2020) 1.

  • Sitotaw D B, J Eng (United Kingdom), 2018 (2018) 1.

  • Islam S, Md. Mominul Alam S & Akter S, Materials Today Proceedings, (38) (2021) 2563.

  • Senthilkumar M, Dynamics of Elastic Knitted Fabrics for Tight Fit Sportswear, Ph.D. Thesis, Anna University, Chennai, 2014.

  • Senthilkumar M, Sounderraj S & Anbumani N, J Text Apparel, Technol Management, 7(4) (2012) 1.

  • Abdessalem S Ben, Abidi F, Mokhtar S & Elmarzougui S, Res J Text Apparel, 12(4) (2008) 61.

  • Di Bartolomeo L, Investigation into Elastic Performance and Functionality of Fabrics for Medical Pressure Garments, Ph.D. Thesis, RMIT University, Melbourne, 2014.

  • Ahirwar M, J Text Eng Fashion Technol, 6(5) (2020) 169.

  • Miller R W, Text Res J, 72(7) (2002) 601.

  • Besler N, Gloy Y S & Gries T, IOP Conference Series: Materials Sci Eng, 141(1) (2016) 1.

  • Pervez M N, Talukder M E, Datta M K, Mia M S, Zaman A, Khan M M R, Cai Y & Lin L, MATEC Web of Conferences, 130 (2017) 1.

  • Epps H H, Color Res Application, 28(3) (2003) 230.

  • Nazir A, Hussain T, Rehman A & Abid A, J Text Apparel, Technol Management, 9 (2) (2015) 1.

  • https://www. cottoninc.com/wp-content/uploads/2017/12/TRI-3012-Wet- Processing-of-Cotton-Spandex-Fabric.pdf, (2004) [accessed 3 Sep. 2021].

  • Hasanbeigi A, Technical Report - Energy Effeciency Imporvement opportunity for the Textile Industry (Lawrence Berkeley National Laboratory), 2010 136.

  • Yasin S, Curti M, Behary N, Perwuelz A, Giraud S, Rover G, Guan J & Chen G, Surface Rev Letters, 24(8) (2017) 1.

  • Rasyid M F A, Salim M S, Akil H M & Ishak Z A M, Procedia Chem, 19 (2016) 469.

  • Hasanuzzaman, Dan P K & Basu S, J Text Inst, 106(5) (2015) 510.

  • Lin Y, Choi K F, Zhang M, Li Y, Luximon A, Yao L & Hu J, Text Res J, 82 (2) (2012) 108.

  • Wang Y, Zhang P & Zhang Y, Text Res J, 84(6) (2014) 572.

  • Islam S, Alam S M M & Akter S, Res J Text Apparel, 22(3) (2018) 260.

  • Vigneswaran C, Chandrasekaran K & Senthilkumar P, J Industrial Text, 38(4) (2009) 289.

  • Ajeli S & Minapoor S, J Text Inst, 103(5) (2012) 523.

  • Kumar V & SampathV R, Fibres Text East Eur, 99(3) (2013) 73.

  • Higgins L, Anand S C, Hall M E & Holmes D A, J Text Inst, 94(1–2) (2003) 119.

  • Yim K Y & Kan C W, Text Res J, 88(4) (2018) 467.

  • Kakvan A, Shaikhzadeh Najar S & Psikuta A, J Text Inst, 106(6) (2015) 674.


Abstract Views: 80

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  • Heat-Setting Parameters Optimisation of Cotton/Elastane Fabric Using Response Surface Methodology

Abstract Views: 80  |  PDF Views: 65

Authors

Nur Athirah Huzaisham
Department of Mechanical Engineering Technology, Faculty of Engineering Technology, Universiti Tun Hussein Onn Malaysia, 84600 Pagoh, Muar, Johor, Malaysia
Siti Hana Nasir
Department of Mechanical Engineering Technology, Faculty of Engineering Technology, Universiti Tun Hussein Onn Malaysia, 84600 Pagoh, Muar, Johor, Malaysia
Muhammad Khalis Mohd Idris
Department of Mechanical Engineering Technology, Faculty of Engineering Technology, Universiti Tun Hussein Onn Malaysia, 84600 Pagoh, Muar, Johor, Malaysia
Carolina Quintero Rodriguez
School of Fashion and Textiles, RMIT University, Melbourne, Australia

Abstract


The effect of heat-setting treatment on the performance of cotton/elastane fabric has been studied. Response surface methodology has been used to design the experiments where temperature (°C), time (s) and fabric width extension (%) are taken as factor variables. Fabric dimension (lengthwise and widthwise), fabric areal density and fabric tension decay are taken as response variables. The findings establish that the optimum heat-setting parameters are 190℃ temperature, 75s process time and 13.5% width extension. It is necessary to optimise the heat-setting parameters to achieve better fabric dimensional stability, as overheating damages and deteriorates some of the elastane filaments, resulting in reduced recovery properties after a certain temperature point.

Keywords


Cotton/Elastane Fabric, Dimensional Stability, Elastane, Heat-Setting Treatment, Knitted Fabric, Single Jersey Fabric, Tension Decay.

References