Research Article
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A Novel Approach for Developing Smart Cotton Fabric with Dynamic Breathability and Easy Care Features

Year 2023, Volume: 33 Issue: 3, 238 - 248, 30.09.2023
https://doi.org/10.32710/tekstilvekonfeksiyon.1065260

Abstract

In this study, cotton fabrics were treated with temperature-water responsive nanocomposites consisting of shape memory polyurethane (SMPU) and cellulose nanowhiskers (CNWs), for smart crease recovery/retention functions besides breathability with dynamic porosity. The smart crease recovery/retention functions were determined in air/water at different temperatures and relative humidity simulating laundry and drying processes and air permeability test was conducted at different fabric temperatures. Also, physical-mechanical properties (weight, thickness, bending rigidity, and strength) and washing fastness properties were evaluated. Fourier-transform infrared (FT-IR) and scanning electron microscope (SEM) analyses confirm the SMPU-CNW nanocomposite presence on fabric. Test results show that the treated cotton fabrics have not only dual responsive shape memory properties providing smart permeability, but also dynamic crease recovery/retention with enhanced mechanical properties. This method could contribute t ecological and economic aspects of sustainability as a result of less energy and polymer consumption with non-ironing property and treatment procedures and low chemical footprint.

Supporting Institution

Scientific and Technological Council of Turkey, Süleyman Demirel University

Project Number

118M228, 05424-DR-14

Thanks

This study was funded by the Scientific and Technological Council of Turkey (Project No. 118M228) and Süleyman Demirel University (Project No. 05424-DR-14). Furthermore, the authors would like to express their gratitude to Söktaş Group and also Pulcra Chemicals for fabric and chemical material supply, respectively.

References

  • Sarwar N, Humayoun UB, Nawaz A, Yoon DH. 2021. Development of sustainable, cost effective foam finishing approach for cellulosic textile employing succinic acid/xylitol crosslinking system Sustainable Materials and Technologies 30, e00350.
  • Korkmaz N, Alay Aksoy S. 2016. Enhancing the performance properties of ester-cross-linked cotton fabrics using Al2O3-NPs Textile Research Journal 86(6), 636-648.
  • Xiao C, Sun F, Iqbal MI, Liu L, Gao W. 2021. Mechanical characterization of surface wrinkling properties in fibrous sheet materials by facile folding process Polymer Testing 97, 107153.
  • Patil NV, Netravali AN. 2020. Multifunctional sucrose acid as a ‘green’ crosslinker for wrinkle-free cotton fabrics Cellulose 27(9), 5407-5420.
  • Lu J, Hu JL, Zhu Y, Liu YJ. 2012. Shape memory finishing of wool fabrics and garments Advanced Materials Research 441, 235-238.
  • Harifi T, Montazer M. 2012. Past, present and future prospects of cotton cross-linking: New insight into nano particles Carbohydrate Polymers 88(4), 1125-1140.
  • Haule LV, Nambela L. 2022. Sustainable application of nanomaterial for finishing of textile material. In Shanker U, Mustansar Hussain C, Rani M. (Ed.), Green Nanomaterials for Industrial Applications. Oxford: Elsevier, 177-206.
  • Wang H, Zhang C, Chu X, Zhu P. 2020. Mechanism of antiwrinkle finishing of cotton fabrics using mixed polycarboxylic acids International Journal of Polymer Science. Retrieved from https://doi.org/10.1155/2020/3876595.
  • Lou J, Wang D, Fan X. 2022. Preparation, characterization of carboxyl polyaldehyde sugars and application as innovative anti-crease finishing agents for cotton fabric Journal of Natural Fibers, 1-8.
  • Arık B, Yavaş A, Avinc, O. 2017. Antibacterial and wrinkle resistance improvement of nettle biofibre using Chitosan and BTCA Fibres & Textiles in Eastern Europe 25, 106-111.
  • Mohsin M, Sarwar N, Ahmad S, Rasheed A, Ahmad F, Afzal A, Zafar S. 2016. Maleic acid crosslinking of C-6 fluorocarbon as oil and water repellent finish on cellulosic fabrics Journal of Cleaner Production 112, 3525-3530.
  • Kang IS, Yang CQ, Wei W, Lickfield GC. 1998. Mechanical strength of durable press finished cotton fabrics: Part I: Effects of acid degradation and crosslinking of cellulose by polycarboxylic acids Textile Research Journal 68(11), 865-870.
  • Xu H, Canisag H, Mu B, Yang Y. 2015. Robust and flexible films from 100% starch cross-linked by biobased disaccharide derivative ACS Sustainable Chemistry & Engineering 3(11), 2631-2639.
  • Dadashian F, Montazer M, Ferdowsi S. 2010. Lipases improve the grafting of poly (ethylene terephthalate) fabrics with acrylic acid Journal of Applied Polymer Science 116(1), 203-209.
  • Sarwar N, Mohsin M, Bhatti AA, Ahmmad SW, Husaain A. 2017. Development of water and energy efficient environment friendly easy care finishing by foam coating on stretch denim fabric Journal of Cleaner Production, 154, 159-166.
  • Qi H, Zhao C, Qing FL, Yan K, Sun G. 2016. Antiwrinkle finishing of cotton fabrics with 5-(Carbonyloxy succinic)-benzene-1, 2, 4-tricarboxylic acid: Comparison with other acids Industrial & Engineering Chemistry Research 55(46), 11850-11856.
  • Li YKS. 2006. Evaluation of shape memory fabrics (Master of Philosophy dissertation). Retrieved from/Available from The Hong Kong Polytechnic University Thesis Center.
  • Liu X, Hu J, Murugesh Babu K, Wang S. 2008. Elasticity and shape memory effect of shape memory fabrics Textile Research Journal 78(12), 1048-1056.
  • Korkmaz Memiş N, Kaplan S. 2019, November. Improving dynamic crease recovery and retention features of wool fabrics by shape memory nanocomposites. Proceedings of the 17th National 3rd International The Recent Progress Symposium on Textile Technology and Chemistry (137-143), Bursa, Turkey.
  • Korkmaz Memiş N, Kaplan S. 2019, June. Dynamic crease recovery and retention of wool fabric by shape memory polyurethane. Proceedings of the 47th Textile Research Symposium (79-80), Liberec, Czechia.
  • Korkmaz Memiş N. 2020. Textile applications of cellulose nanowhisker reinforced thermo-water responsive polyurethane composite structure (Doctoral dissertation). Retrieved from/Available from Yök National Thesis Center. (615324)
  • Liu Y, Lu, J, Hu J, Chung A. 2013. Study on the bagging behavior of knitted fabrics by shape memory polyurethane fiber Journal of the Textile Institute 104(11), 1230-1236.
  • Korkmaz Memiş N, Kaplan S. 2019, April. Enhancing wool fabric bagging recovery by shape memory polyurethane finishing. Proceedings of the International Congress on Wool and Luxury Fibres – ICONWOOLF 2019 (74-81), Tekirdağ, Turkey.
  • Memiş NK, Kaplan S. 2020. Enhancing wool fabric easy care properties by shape memory polyurethane finishing AATCC Journal of Research 7(3), 26-33.
  • Memiş NK, Kaplan S. 2021. Temperature and moisture responsive nanocomposite treated polyester fabric for smart bagging recovery Indian Journal of Fibre & Textile Research 46(3), 293-302.
  • Ding XM, Hu JL, Tao XM. 2004. Effect of crystal melting on water vapor permeability of shape-memory polyurethane film Textile Research Journal 74, 39-43.
  • Mondal S, Hu JL.2006. Segmented shape memory polyurethane and its water vapor transport properties Designed Monomers and Polymers 9, 527-550.
  • Chen S, Hu J, Liu Y, Liem H, Zhu Y, Meng Q. 2007. Effect of molecular weight on shape memory behavior in polyurethane films Polymer International 56, 1128-1134.
  • Zhu Y, Hu J, Yeung LY, Liu Y, Ji F, Yeung KW. 2006. Development of shape memory polyurethane fiber with complete shape recoverability Smart Materials and Structures 15(5), 1385.
  • Kaursoin J, Agrawal AK. 2007. Melt spun thermoresponsive shape memory fibers based on polyurethanes: Effect of drawing and heat‐setting on fiber morphology and properties Journal of Applied Polymer Science 103(4), 2172-2182.
  • Liu Y, Chung A, Hu J, Lv J. 2007. Shape memory behavior of SMPU knitted fabric Journal of Zhejiang University-Science A 8(5), 830-834.
  • Meng Q, Hu J, Zhu Y, Lu J, Liu Y. 2007. Morphology, phase separation, thermal and mechanical property differences of shape memory fibres prepared by different spinning methods Smart Materials and Structures 16(4), 1192.
  • Zhu Y, Hu J, Yeung LY, Lu J, Meng Q, Chen S, Yeung KW. 2007. Effect of steaming on shape memory polyurethane fibers with various hard segment contents Smart Materials and Structures 16(4), 969.
  • Jing L, Hu J. 2010. Study on the properties of core spun yarn and fabrics of shape memory polyurethane Fibres & Textiles in Eastern Europe 18(4), 39-42.
  • Liu Y, Lu J, Hu J, Chung A. 2013. Study on the bagging behavior of knitted fabrics by shape memory polyurethane fiber Journal of the Textile Institute 104(11), 1230-1236.
  • Yang Q, Li G. 2014. Investigation into stress recovery behavior of shape memory polyurethane fiber Journal of Polymer Science Part B: Polymer Physics 52(21), 1429-1440.
  • Budun S, İşgören E, Erdem R, Yüksek M. 2016. Morphological and mechanical analysis of electrospun shape memory polymer fibers Applied Surface Science 380, 294-300.
  • Aslan S, Kaplan S. 2018. Thermomechanical and shape memory performances of thermo-sensitive polyurethane fibers Fibers and Polymers 19(2), 272-280.
  • Sáenz-Pérez M, Bashir T, Laza JM, García-Barrasa J, Vilas JL, Skrifvars M, León LM. 2019. Novel shape-memory polyurethane fibers for textile applications. Textile Research Journal 89(6), 1027-1037.
  • Gupta P, Garg H, Mohanty J, Kumar B. 2020. Excellent memory performance of poly (1, 6-hexanediol adipate) based shape memory polyurethane filament over a range of thermo-mechanical parameters Journal of Polymer Research 27(12), 1-13.
  • Ni QQ, Guan X, Zhu Y, Dong Y, Xia H. 2020. Nanofiber-based wearable energy harvesters in different body motions Composites Science and Technology 200, 108478.
  • Tonndorf R, Aibibu D, Cherif C. 2020. Thermoresponsive shape memory fibers for compression garments Polymers 12(12), 2989.
  • Guan X, Xia H, Ni QQ. 2021. Shape memory polyurethane‐based electrospun yarns for thermo‐responsive actuation Journal of Applied Polymer Science 138(24), 50565.
  • Shi Y, Chen H, Guan X. 2021. High shape memory properties and high strength of shape memory polyurethane nanofiber-based yarn and coil Polymer Testing 107277.
  • Cho J.W, Jung YC, Chun BC, Chung YC. 2004. Water vapor permeability and mechanical properties of fabrics coated with shape‐memory polyurethane Journal of Applied Polymer Science 92(5), 2812-2816.
  • Yeqiu L, Jinlian H, Yong Z, Zhuohong Y. 2005. Surface modification of cotton fabric by grafting of polyurethane Carbohydrate Polymers 61(3), 276-280.
  • Liem H, Yeung LY, Hu JL. 2007. A prerequisite for the effective transfer of the shape-memory effect to cotton fibers Smart Materials and Structures 16(3), 748.
  • Mondal S, Hu JL. 2007. Water vapor permeability of cotton fabrics coated with shape memory polyurethane Carbohydrate Polymers 67(3), 282-287.
  • Dong ZE, Jinlian H, Liu Y, Liu Y, Kuen Chan L. 2008. The performance evaluation of the woven wool fabrics treated with shape memory polymers International Journal of Sheep and Wool Science 56(1), 8-18.
  • Bao LH, Ma HT. 2017. Preparation of temperature-sensitive polyurethanes based on modified castor oil Fibres & Textiles in Eastern Europe 25, 34-39.
  • Jahid MA, Hu J, Wong K, Wu Y, Zhu Y, Sheng Luo HH, Zhongmin D. 2018. Fabric coated with shape memory polyurethane and its properties Polymers 10(6), 681.
  • Memiş NK, Kaplan S. 2020. Wool fabric having thermal comfort management function via shape memory polyurethane finishing The Journal of The Textile Institute 111(5), 734-744.
  • Korkmaz Memiş N, Kaplan S. 2020. Dual responsive wool fabric by cellulose nanowhisker reinforced shape memory polyurethane Journal of Applied Polymer Science 137(19), 48674.
  • Xia L, Yang F, Wu H, Zhang M, Huang Z, Qiu G, Xin F, Fu W. 2020. Novel series of thermal-and water-induced shape memory Eucommia ulmoides rubber composites Polymer Testing 81, 106212.
  • Luo H. 2012. Study on stimulus-responsive cellulose-based polymeric materials (Doctoral dissertation). Retrieved from/Available from The Hong Kong Polytechnic University Thesis Center.
  • Tan L, Hu J, Ying Rena K, Zhu Y, Liu P. 2017. Quick water‐responsive shape memory hybrids with cellulose nanofibers Journal of Polymer Science Part A: Polymer Chemistry 55(4), 767-775.
  • Wang Y, Cheng Z, Liu Z, Kang H, Liu Y. 2018. Cellulose nanofibers/polyurethane shape memory composites with fast water-responsivity Journal of Materials Chemistry B 6(11), 1668-1677.
  • Zhu Y, Hu J, Luo H, Young RJ, Deng L, Zhang S, Fan Y, Ye. 2012. Rapidly switchable water-sensitive shape-memory cellulose/elastomer nano-composites Soft Matter 8(8), 2509-2517.
  • Ugarte L, Santamaria-Echart A, Mastel S, Autore M, Hillenbrand R, Corcuera MA, Eceiza A. 2017. An alternative approach for the incorporation of cellulose nanocrystals in flexible polyurethane foams based on renewably sourced polyols Industrial Crops and Products 95, 564-573.
  • Yeqiu L, Jinlian H, Yong Z, Zhuohong Y. 2005. Surface modification of cotton fabric by grafting of polyurethane Carbohydrate Polymers 61(3), 276-280.
  • Kaplan S. Prediction of clothing comfort from mechanical and permeability properties of fabrics (Doctoral dissertation). Retrieved from/Available from Yök National Thesis Center. (243562)
  • Ertekin M, Ertekin G, Marmaralı A. 2018. Analysis of thermal comfort properties of fabrics for protective applications The Journal of The Textile Institute 109(8), 1091-1098.
  • Song G. 2011. Improving comfort in clothing. London: Woodhead Publishing. Wang J, Chen Y, An J, Xu K, Chen T, Müller-Buschbaum P, Zhong Q. 2017. Intelligent textiles with comfort regulation and inhibition of bacterial adhesion realized by cross-linking poly (n-isopropylacrylamide-co-ethylene glycol methacrylate) to cotton fabrics ACS Applied Materials & Interfaces 9(15), 13647-13656.
  • Zhong Q, Lu M, Nieuwenhuis S, Wu BS, Wu GP, Xu ZK, Müller-Buschbaum P, Wang JP. 2019. Enhanced stain removal and comfort control achieved by cross-linking light and thermo dual-responsive copolymer onto cotton fabrics ACS Applied Materials & Interfaces 11(5), 5414-5426.
  • Hu J, Wu Y, Zhang C, Tang BZ, Chen S. 2017. Self-adaptive water vapor permeability and its hydrogen bonding switches of bio-inspired polymer thin films Materials Chemistry Frontiers 1(10), 2027-2030.
  • Follain N, Belbekhouche S, Bras J, Siqueira G, Chappey C, Marais S, Dufresne A. 2018. Tunable gas barrier properties of filled-PCL film by forming percolating cellulose network Colloids and Surfaces A: Physicochemical and Engineering Aspects 545, 26-30.
  • Hu J, Chung S, Li Y. 2007. Characterization about the shape memory behaviour of woven fabrics Transactions of the Institute of Measurement and Control 29(3-4), 301-319.
  • Sarwar N, Humayoun UB, Khan AA, Kumar M, Nawaz A, Yoo JH, Yoon DH. 2020. Engineering of sustainable clothing with improved comfort and thermal properties-A step towards reducing chemical footprint Journal of Cleaner Production 261, 121189.
Year 2023, Volume: 33 Issue: 3, 238 - 248, 30.09.2023
https://doi.org/10.32710/tekstilvekonfeksiyon.1065260

Abstract

Project Number

118M228, 05424-DR-14

References

  • Sarwar N, Humayoun UB, Nawaz A, Yoon DH. 2021. Development of sustainable, cost effective foam finishing approach for cellulosic textile employing succinic acid/xylitol crosslinking system Sustainable Materials and Technologies 30, e00350.
  • Korkmaz N, Alay Aksoy S. 2016. Enhancing the performance properties of ester-cross-linked cotton fabrics using Al2O3-NPs Textile Research Journal 86(6), 636-648.
  • Xiao C, Sun F, Iqbal MI, Liu L, Gao W. 2021. Mechanical characterization of surface wrinkling properties in fibrous sheet materials by facile folding process Polymer Testing 97, 107153.
  • Patil NV, Netravali AN. 2020. Multifunctional sucrose acid as a ‘green’ crosslinker for wrinkle-free cotton fabrics Cellulose 27(9), 5407-5420.
  • Lu J, Hu JL, Zhu Y, Liu YJ. 2012. Shape memory finishing of wool fabrics and garments Advanced Materials Research 441, 235-238.
  • Harifi T, Montazer M. 2012. Past, present and future prospects of cotton cross-linking: New insight into nano particles Carbohydrate Polymers 88(4), 1125-1140.
  • Haule LV, Nambela L. 2022. Sustainable application of nanomaterial for finishing of textile material. In Shanker U, Mustansar Hussain C, Rani M. (Ed.), Green Nanomaterials for Industrial Applications. Oxford: Elsevier, 177-206.
  • Wang H, Zhang C, Chu X, Zhu P. 2020. Mechanism of antiwrinkle finishing of cotton fabrics using mixed polycarboxylic acids International Journal of Polymer Science. Retrieved from https://doi.org/10.1155/2020/3876595.
  • Lou J, Wang D, Fan X. 2022. Preparation, characterization of carboxyl polyaldehyde sugars and application as innovative anti-crease finishing agents for cotton fabric Journal of Natural Fibers, 1-8.
  • Arık B, Yavaş A, Avinc, O. 2017. Antibacterial and wrinkle resistance improvement of nettle biofibre using Chitosan and BTCA Fibres & Textiles in Eastern Europe 25, 106-111.
  • Mohsin M, Sarwar N, Ahmad S, Rasheed A, Ahmad F, Afzal A, Zafar S. 2016. Maleic acid crosslinking of C-6 fluorocarbon as oil and water repellent finish on cellulosic fabrics Journal of Cleaner Production 112, 3525-3530.
  • Kang IS, Yang CQ, Wei W, Lickfield GC. 1998. Mechanical strength of durable press finished cotton fabrics: Part I: Effects of acid degradation and crosslinking of cellulose by polycarboxylic acids Textile Research Journal 68(11), 865-870.
  • Xu H, Canisag H, Mu B, Yang Y. 2015. Robust and flexible films from 100% starch cross-linked by biobased disaccharide derivative ACS Sustainable Chemistry & Engineering 3(11), 2631-2639.
  • Dadashian F, Montazer M, Ferdowsi S. 2010. Lipases improve the grafting of poly (ethylene terephthalate) fabrics with acrylic acid Journal of Applied Polymer Science 116(1), 203-209.
  • Sarwar N, Mohsin M, Bhatti AA, Ahmmad SW, Husaain A. 2017. Development of water and energy efficient environment friendly easy care finishing by foam coating on stretch denim fabric Journal of Cleaner Production, 154, 159-166.
  • Qi H, Zhao C, Qing FL, Yan K, Sun G. 2016. Antiwrinkle finishing of cotton fabrics with 5-(Carbonyloxy succinic)-benzene-1, 2, 4-tricarboxylic acid: Comparison with other acids Industrial & Engineering Chemistry Research 55(46), 11850-11856.
  • Li YKS. 2006. Evaluation of shape memory fabrics (Master of Philosophy dissertation). Retrieved from/Available from The Hong Kong Polytechnic University Thesis Center.
  • Liu X, Hu J, Murugesh Babu K, Wang S. 2008. Elasticity and shape memory effect of shape memory fabrics Textile Research Journal 78(12), 1048-1056.
  • Korkmaz Memiş N, Kaplan S. 2019, November. Improving dynamic crease recovery and retention features of wool fabrics by shape memory nanocomposites. Proceedings of the 17th National 3rd International The Recent Progress Symposium on Textile Technology and Chemistry (137-143), Bursa, Turkey.
  • Korkmaz Memiş N, Kaplan S. 2019, June. Dynamic crease recovery and retention of wool fabric by shape memory polyurethane. Proceedings of the 47th Textile Research Symposium (79-80), Liberec, Czechia.
  • Korkmaz Memiş N. 2020. Textile applications of cellulose nanowhisker reinforced thermo-water responsive polyurethane composite structure (Doctoral dissertation). Retrieved from/Available from Yök National Thesis Center. (615324)
  • Liu Y, Lu, J, Hu J, Chung A. 2013. Study on the bagging behavior of knitted fabrics by shape memory polyurethane fiber Journal of the Textile Institute 104(11), 1230-1236.
  • Korkmaz Memiş N, Kaplan S. 2019, April. Enhancing wool fabric bagging recovery by shape memory polyurethane finishing. Proceedings of the International Congress on Wool and Luxury Fibres – ICONWOOLF 2019 (74-81), Tekirdağ, Turkey.
  • Memiş NK, Kaplan S. 2020. Enhancing wool fabric easy care properties by shape memory polyurethane finishing AATCC Journal of Research 7(3), 26-33.
  • Memiş NK, Kaplan S. 2021. Temperature and moisture responsive nanocomposite treated polyester fabric for smart bagging recovery Indian Journal of Fibre & Textile Research 46(3), 293-302.
  • Ding XM, Hu JL, Tao XM. 2004. Effect of crystal melting on water vapor permeability of shape-memory polyurethane film Textile Research Journal 74, 39-43.
  • Mondal S, Hu JL.2006. Segmented shape memory polyurethane and its water vapor transport properties Designed Monomers and Polymers 9, 527-550.
  • Chen S, Hu J, Liu Y, Liem H, Zhu Y, Meng Q. 2007. Effect of molecular weight on shape memory behavior in polyurethane films Polymer International 56, 1128-1134.
  • Zhu Y, Hu J, Yeung LY, Liu Y, Ji F, Yeung KW. 2006. Development of shape memory polyurethane fiber with complete shape recoverability Smart Materials and Structures 15(5), 1385.
  • Kaursoin J, Agrawal AK. 2007. Melt spun thermoresponsive shape memory fibers based on polyurethanes: Effect of drawing and heat‐setting on fiber morphology and properties Journal of Applied Polymer Science 103(4), 2172-2182.
  • Liu Y, Chung A, Hu J, Lv J. 2007. Shape memory behavior of SMPU knitted fabric Journal of Zhejiang University-Science A 8(5), 830-834.
  • Meng Q, Hu J, Zhu Y, Lu J, Liu Y. 2007. Morphology, phase separation, thermal and mechanical property differences of shape memory fibres prepared by different spinning methods Smart Materials and Structures 16(4), 1192.
  • Zhu Y, Hu J, Yeung LY, Lu J, Meng Q, Chen S, Yeung KW. 2007. Effect of steaming on shape memory polyurethane fibers with various hard segment contents Smart Materials and Structures 16(4), 969.
  • Jing L, Hu J. 2010. Study on the properties of core spun yarn and fabrics of shape memory polyurethane Fibres & Textiles in Eastern Europe 18(4), 39-42.
  • Liu Y, Lu J, Hu J, Chung A. 2013. Study on the bagging behavior of knitted fabrics by shape memory polyurethane fiber Journal of the Textile Institute 104(11), 1230-1236.
  • Yang Q, Li G. 2014. Investigation into stress recovery behavior of shape memory polyurethane fiber Journal of Polymer Science Part B: Polymer Physics 52(21), 1429-1440.
  • Budun S, İşgören E, Erdem R, Yüksek M. 2016. Morphological and mechanical analysis of electrospun shape memory polymer fibers Applied Surface Science 380, 294-300.
  • Aslan S, Kaplan S. 2018. Thermomechanical and shape memory performances of thermo-sensitive polyurethane fibers Fibers and Polymers 19(2), 272-280.
  • Sáenz-Pérez M, Bashir T, Laza JM, García-Barrasa J, Vilas JL, Skrifvars M, León LM. 2019. Novel shape-memory polyurethane fibers for textile applications. Textile Research Journal 89(6), 1027-1037.
  • Gupta P, Garg H, Mohanty J, Kumar B. 2020. Excellent memory performance of poly (1, 6-hexanediol adipate) based shape memory polyurethane filament over a range of thermo-mechanical parameters Journal of Polymer Research 27(12), 1-13.
  • Ni QQ, Guan X, Zhu Y, Dong Y, Xia H. 2020. Nanofiber-based wearable energy harvesters in different body motions Composites Science and Technology 200, 108478.
  • Tonndorf R, Aibibu D, Cherif C. 2020. Thermoresponsive shape memory fibers for compression garments Polymers 12(12), 2989.
  • Guan X, Xia H, Ni QQ. 2021. Shape memory polyurethane‐based electrospun yarns for thermo‐responsive actuation Journal of Applied Polymer Science 138(24), 50565.
  • Shi Y, Chen H, Guan X. 2021. High shape memory properties and high strength of shape memory polyurethane nanofiber-based yarn and coil Polymer Testing 107277.
  • Cho J.W, Jung YC, Chun BC, Chung YC. 2004. Water vapor permeability and mechanical properties of fabrics coated with shape‐memory polyurethane Journal of Applied Polymer Science 92(5), 2812-2816.
  • Yeqiu L, Jinlian H, Yong Z, Zhuohong Y. 2005. Surface modification of cotton fabric by grafting of polyurethane Carbohydrate Polymers 61(3), 276-280.
  • Liem H, Yeung LY, Hu JL. 2007. A prerequisite for the effective transfer of the shape-memory effect to cotton fibers Smart Materials and Structures 16(3), 748.
  • Mondal S, Hu JL. 2007. Water vapor permeability of cotton fabrics coated with shape memory polyurethane Carbohydrate Polymers 67(3), 282-287.
  • Dong ZE, Jinlian H, Liu Y, Liu Y, Kuen Chan L. 2008. The performance evaluation of the woven wool fabrics treated with shape memory polymers International Journal of Sheep and Wool Science 56(1), 8-18.
  • Bao LH, Ma HT. 2017. Preparation of temperature-sensitive polyurethanes based on modified castor oil Fibres & Textiles in Eastern Europe 25, 34-39.
  • Jahid MA, Hu J, Wong K, Wu Y, Zhu Y, Sheng Luo HH, Zhongmin D. 2018. Fabric coated with shape memory polyurethane and its properties Polymers 10(6), 681.
  • Memiş NK, Kaplan S. 2020. Wool fabric having thermal comfort management function via shape memory polyurethane finishing The Journal of The Textile Institute 111(5), 734-744.
  • Korkmaz Memiş N, Kaplan S. 2020. Dual responsive wool fabric by cellulose nanowhisker reinforced shape memory polyurethane Journal of Applied Polymer Science 137(19), 48674.
  • Xia L, Yang F, Wu H, Zhang M, Huang Z, Qiu G, Xin F, Fu W. 2020. Novel series of thermal-and water-induced shape memory Eucommia ulmoides rubber composites Polymer Testing 81, 106212.
  • Luo H. 2012. Study on stimulus-responsive cellulose-based polymeric materials (Doctoral dissertation). Retrieved from/Available from The Hong Kong Polytechnic University Thesis Center.
  • Tan L, Hu J, Ying Rena K, Zhu Y, Liu P. 2017. Quick water‐responsive shape memory hybrids with cellulose nanofibers Journal of Polymer Science Part A: Polymer Chemistry 55(4), 767-775.
  • Wang Y, Cheng Z, Liu Z, Kang H, Liu Y. 2018. Cellulose nanofibers/polyurethane shape memory composites with fast water-responsivity Journal of Materials Chemistry B 6(11), 1668-1677.
  • Zhu Y, Hu J, Luo H, Young RJ, Deng L, Zhang S, Fan Y, Ye. 2012. Rapidly switchable water-sensitive shape-memory cellulose/elastomer nano-composites Soft Matter 8(8), 2509-2517.
  • Ugarte L, Santamaria-Echart A, Mastel S, Autore M, Hillenbrand R, Corcuera MA, Eceiza A. 2017. An alternative approach for the incorporation of cellulose nanocrystals in flexible polyurethane foams based on renewably sourced polyols Industrial Crops and Products 95, 564-573.
  • Yeqiu L, Jinlian H, Yong Z, Zhuohong Y. 2005. Surface modification of cotton fabric by grafting of polyurethane Carbohydrate Polymers 61(3), 276-280.
  • Kaplan S. Prediction of clothing comfort from mechanical and permeability properties of fabrics (Doctoral dissertation). Retrieved from/Available from Yök National Thesis Center. (243562)
  • Ertekin M, Ertekin G, Marmaralı A. 2018. Analysis of thermal comfort properties of fabrics for protective applications The Journal of The Textile Institute 109(8), 1091-1098.
  • Song G. 2011. Improving comfort in clothing. London: Woodhead Publishing. Wang J, Chen Y, An J, Xu K, Chen T, Müller-Buschbaum P, Zhong Q. 2017. Intelligent textiles with comfort regulation and inhibition of bacterial adhesion realized by cross-linking poly (n-isopropylacrylamide-co-ethylene glycol methacrylate) to cotton fabrics ACS Applied Materials & Interfaces 9(15), 13647-13656.
  • Zhong Q, Lu M, Nieuwenhuis S, Wu BS, Wu GP, Xu ZK, Müller-Buschbaum P, Wang JP. 2019. Enhanced stain removal and comfort control achieved by cross-linking light and thermo dual-responsive copolymer onto cotton fabrics ACS Applied Materials & Interfaces 11(5), 5414-5426.
  • Hu J, Wu Y, Zhang C, Tang BZ, Chen S. 2017. Self-adaptive water vapor permeability and its hydrogen bonding switches of bio-inspired polymer thin films Materials Chemistry Frontiers 1(10), 2027-2030.
  • Follain N, Belbekhouche S, Bras J, Siqueira G, Chappey C, Marais S, Dufresne A. 2018. Tunable gas barrier properties of filled-PCL film by forming percolating cellulose network Colloids and Surfaces A: Physicochemical and Engineering Aspects 545, 26-30.
  • Hu J, Chung S, Li Y. 2007. Characterization about the shape memory behaviour of woven fabrics Transactions of the Institute of Measurement and Control 29(3-4), 301-319.
  • Sarwar N, Humayoun UB, Khan AA, Kumar M, Nawaz A, Yoo JH, Yoon DH. 2020. Engineering of sustainable clothing with improved comfort and thermal properties-A step towards reducing chemical footprint Journal of Cleaner Production 261, 121189.
There are 68 citations in total.

Details

Primary Language English
Subjects Wearable Materials
Journal Section Articles
Authors

Nazife Korkmaz Memiş 0000-0003-1605-0670

Sibel Kaplan 0000-0002-7247-135X

Project Number 118M228, 05424-DR-14
Early Pub Date September 30, 2023
Publication Date September 30, 2023
Submission Date January 30, 2022
Acceptance Date October 13, 2022
Published in Issue Year 2023 Volume: 33 Issue: 3

Cite

APA Korkmaz Memiş, N., & Kaplan, S. (2023). A Novel Approach for Developing Smart Cotton Fabric with Dynamic Breathability and Easy Care Features. Textile and Apparel, 33(3), 238-248. https://doi.org/10.32710/tekstilvekonfeksiyon.1065260

No part of this journal may be reproduced, stored, transmitted or disseminated in any forms or by any means without prior written permission of the Editorial Board. The views and opinions expressed here in the articles are those of the authors and are not the views of Tekstil ve Konfeksiyon and Textile and Apparel Research-Application Center.