KESİKLİ POLİESTER VE DIŞ/İÇ DÜŞÜK SICAKLIKTA ERİYEN KESİKLİ POLİESTER BAĞLAYICI LİFLERİNDEN TARAK, İĞNELEME VE PRES MAKİNELERİ İLE ÜRETİLMİŞ DOKUNMAMIŞ KUMAŞLARIN MUKAVEMET ÖZELLİKLERİ ÜZERİNE BİR ARAŞTIRMA

Bu çalışmada, kesikli poliester liflerinden ve dış/iç düşük sıcaklıkta eriyen kesikli bağlayıcı poliester liflerinden, farklı karışım oranlarında, tarak prosesi ve sonrasında iğneleme ve sıcak pres ile ısı ile bağlama yapılarak dokunmamış kumaşlar üretilmiştir. İğnelenmiş ve ısı ile bağlanmış dokunmamış kumaşların mukavemet özelliklerinde dış/iç düşük sıcaklıkta eriyen bağlayıcı poliester liflerin etkisi araştırılmıştır. Dış/iç düşük sıcaklıkta eriyen bağlayıcı poliester lifleri %5, %10, %20, %30, %40 ve %50 oranlarında kesikli poliester lifleri ile karıştırılmıştır. Tülbent dokular tarak makinesinde oluşturulmuş ve sonrasında iğneleme ve pres makinelerinde mekanik ve ısıl yöntemlerle bağlanmıştır. Üretilen iğnelenmiş ve ısı ile bağlanmış dokunmamış kumaşların birim metre kare ağırlığı, kalınlık, mukavemet ve kopma anında uzama özellikleri ISO ve ASTM standartlarına göre test edilmiştir. Deneysel sonuçlar çok açık bir şekilde, dış/iç düşük sıcaklıkta eriyen poliester bağlayıcı lif oranının artmasıyla, iğnelenmiş ve ısı ile bağlanmış dokunmamış kumaş mukavemetinin arttığını göstermiştir. %30 ve daha fazla oranda dış/iç düşük sıcaklıkta eriyen poliester bağlayıcı elyaf kullanıldığında, iğnelenmiş ve ısı ile bağlanmış dokunmamış kumaş mukavemetinin hem makine hem de makine yönüne dik yönde önemli oranda arttığı gözlenmiştir. Dış/iç düşük sıcaklıkta eriyen poliester bağlayıcı lif oranının artmasıyla, iğnelenmiş ve ısı ile bağlanmış dokunmamış kumaşların kalınlık değerlerinin de azaldığı tespit edilmiştir.

A RESEARCH ON TENSILE PROPERTIES OF NONWOVEN FABRICS PRODUCED FROM STAPLE POLYESTER AND SHEATH/CORE LOW MELTING STAPLE POLYESTER BINDER FIBRES WITH CARDING, NEEDLE PUNCHING AND PRESSING MACHINES

In this study, nonwoven fabrics were produced from staple polyester fibres and sheath/core low melting staple polyester binder fibres at different blending ratios by carding processes and then post-bonding processes such as needle punching and thermal bonding with pressing. The effect of sheath/core low melting polyester binder fibre ratio on tensile properties of needle punched and thermally bonded nonwoven fabrics was investigated. Sheath/core low melting staple polyester binder fibres were blended with staple polyester fibres at the ratios 5%, 10%, 20%, 30%, 40% and 50%. Webs were formed at carding machine and then bonded mechanically and thermally at needle punching and pressing machines. Fabric area density, thickness, fabric tenacity and elongation at break properties of the produced needle punched and thermally bonded nonwoven fabrics were tested according to ISO and ASTM standards. Experimental results clearly revealed that tenacity values of needle punched and thermally bonded nonwoven fabrics increased with increasing of sheath/core low melting polyester binder fibre ratio. It was observed that as the 30% and higher low melting polyester binder fibre ratios were used, the tenacity values of needle punched and thermally bonded nonwoven fabrics dramatically increased both machine and cross direction. It was found that needle punched and thermally bonded nonwoven fabric thickness values decreased with increasing of sheath/core low melting staple polyester binder fibre ratio.

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1. Özen, M.S.; Sancak, E.: (2016) "Investigation of Tensile Properties of Nonwoven Fabrics Produced from Recycled Staple Polyester and Sheath/core Low Melting Staple Polyester Fibres by Using Carding, Needle Punching, Calendaring and Pressing Machines", International Nonwoven Technical Textiles Technology Magazine, September&October, Number56, pp.42-55.
2. http://www.toray.com/news/fiber
3. Dasdemir, M.; Maze, B.; Anantharamaiah, N.; Pourdeyhimi, B.: (2012) "Influence of Polymer Type, Composition, and Interface on the Structural and Mechanical Properties of Sheath/core Type Bicomponent Nonwoven Fibers", Journal of Material Science, (2012), 45, pp.5955-5969.
4. Turbak, A.F.: "Nonwovens: Theory, Process, Performance, and Testing, Chatper2: Nonwoven Terminology WlliamE.Houfek", Tappi Press, (1993), pp. 11, 167.
5. Akalın, M.; Özen, M.S.: "Tülbent Esaslı Dokunmamış Kumaşlar", (Nonwoven Fabrics)", NesilMatbaacılık, Istanbul (2010) 6. Kellie, G.: (2016), "Advances in Technical Nonwovens", Woodhead Publishing, Number:181, UK.
7. Russell, S.J.: (2007) "Handbook of Nonwovens", Woodhead Publishing in Textiles, CRC Press.
8. Horrocks, A.R.; Anand, S.C.: (2000), "Handbook of Technical Textiles", CRC Press, Boca Raton, USA.
9. Berlin, A.A.; Joswik, R.; Vatin, N.I.: (2016) "Engineering TextilesResearch Methodologies, Concepts, and Modern Applications", AAP Apple Academic Press, Canada, pp.14.
10. Nawab, Y.: (2016), Textile Engineering, Walter de Gruyter GmbH, Germany.
11. Maity, S.; Singha, K.: "Structure-Property Relationship of NeedlePunched Nonwoven Fabric", Frontiers in Science, Vol.2 (6), (2012), pp.226-234
12. Midha, V.K.; Mukhopadyay, A.: "Bulk and Physical Properties of Needle-Punched Nonwoven Fabrics", Indian Journal of Fibre&Textile Research, Vol.30, (2005), pp.218-229.
13. Saghafi, R.; Zarrebini, M.; Moezzi, M.: "Mechanical Properties of Needle-Punched Fabrics in Relation to Fiber Orientation", Journal of Textiles and Polymers, Vol.5, No:1, (2017-Jan), pp.48.
14. Kang, T.J.; Jung, K.H.; Park, J.K.; Youn, J.R.: "Effect of Punching Density on the Mechanical and Thermal Properties of NeedlePunched Nonwoven Carbon/Phenolic Composites", Polymers& Polymer Composites, Vol.10, No.7, (2002), pp.521-530.
15. Anandjiwala, R.D.; &Boguslavsky, L.: "Development of NeedlePunched Nonwoven Fabrics from Flax Fibers for Air Filtration Applications", Textile Research Journal, (2008), Vol.78, pp.614- 624.
16. Ventura, H.; Ardanuy, M.; Capdevila, X.; Cano&Jose, F.; Tornero, A.: "Effects of Needling Parameters on Some Structural and Physico-Mechanical Properties of Needle-Punched Nonwovens", The Journal of The Textile Institute, Vol.105, No.10, pp.1065-1075.
17. Desai, A.N.; Balasubramanian, N.: "Critical Factors Affecting the Properties of Thermal-Bonded Nonwovens with Special Reference to Cellulosic Fibres", Indian Journal of Fibre&Textile Research, Vol.19, September, (1994), pp.209-215.
18. Michielsen, S.; Pourdeyhimi, B.; Desai, P.: "Review of Thermally Point-Bonded Nonwovens: Materials, Processes, and Properties, Journal of Applied Polymer Science, Vol.99, Issue:5, (2006), pp.2489-2496.
19. Bahari, N.; Hasani, H.; Zarrebini, M.; Hassanzadeh, S.: "Investigating the Effects of Material and Process Variables on the Mechanical Properties of Low-Density Thermally Bonded Nonwovens Produced from Estabragh (milkweed) Natural Fibers", Journal of Industrial Textiles, Vol.46, Issue:3, (2016), pp.719-736.
20. Lu, L.; Xing, D.; Xie, Y.: (2016) "Electrical Conductivity Investigation of a Nonwoven Fabric Composed of Carbon Fibers and Polypropylene/Polyethylene Sheath/core Bicomponent Fibers", Materials&Design, Vol.112, pp.383-391
21. Dedov, A.; Nazarov, V.G.: (2015) "Processed Nonwoven Needle Punched Materials with Increased Strength", Fibre Chemistry Vol.47, Issue2, pp.121-125
22. Kim, K-Y.; Doh, S.J.; Im, J.N.: (2013) "Effects of Binder Fibers and Bonding Processes on PET Hollow Fiber Nonwoveens for Automotive Cushion Materials", Fibers and Polymers, Vol.14, Issue4, pp.639-646.
23. Suvari, F.; Ulcay, Y.; Maze, B.: (2013) "Acoustical Abrorptive Properties of Spunbonded Nonwovens Made from Islands-in-theSea Bicomponent Filaments", Journal of the Textile Institute, Vol.104, Issue4, pp.438-445
24. Fages, E.; Cano, M.A.; Girones, S.: (2013) "The Use of Wet-Laid Techniques to Obtain Flax Nonwovens with Different Thermoplastic Binding Fibers for Technical Insulation Applications", Textile Research Journal, Vol.83, Issue4, pp.426- 437.
25. Zhang, H.; Qian, X.; Zhen, Q.: (2015) "Research on Structure Characteristics and Filtration Performances of PET-PA6 Hollow Segmented-Pie Bicomponent Spunbond Nonwovens Fibrillated by Hydro Entangle Method", Journal of Industrial Textiles, Vol.45, Issue1, pp.48-65
26. Doh, S.J.; Lee, J.Y.; Lim, D.Y.: (2013) "Manufacturing and Analyses of Wet-Laid Nonwoven Consisting of Carboxymethyl Cellulose Fibers", Fibers and Polymers, Vol.14, Issue12, pp.2176- 2184.
27. Gordon, S.; Hsieh, Y-L.: (2007) "Cotton: Science and Technology", Woodhead Publishing Limited, Cambridge, England, pp508.
28. Federova, N.: (2006) "Investigation of the Utility of Islands-in-theSea BicomponentFiber Technology in the Spunbond Process", PHd Thesis, North Caroline State University, pp.79.
29. Demirci, E.: "Mechanical Behaviour of Thermally Bonded Bicomponent Fibre Nonwovens: Experimental Analysis and Numerical Modelling", Loughborough University, (2011), pp.37.
30. Midha, V.; Mukhopadyay, A.: "Bulk and Physical Properties of Needle-Punched Nonwoven Fabrics", Indian Journal of Fibre&Textile Research, Vol.30, June (2005), pp.219
31. Ghali, L.; Halimi, M.T.; Hassen, M.B.; Sakli, F.: "Effect of Blending Ratio of Fibers on the Properties of Nonwoven Fabrics Based on Alfa Fibers", Advances in Materials Physics and Chemistry, (2014), 4, pp.116-125.
32. Tracton, A.A.: "Coatings Materials and Surface Coatings", CRC Press, (2007), pp.68-9