The Research on the Production of Bio-based Polyamides 56 Sheath-core Composite Modified Fiber
International Journal of Materials Science and Applications
Volume 5, Issue 2, March 2016, Pages: 79-83
Received: May 3, 2016;
Published: May 4, 2016
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Shouyun Zhang, State Key Laboratory for Modification of Chemical Fibers and Polymer Materials, College of Materials Science and Engineering, Donghua University, Shanghai, P. R. China
Jinghong Ma, State Key Laboratory for Modification of Chemical Fibers and Polymer Materials, College of Materials Science and Engineering, Donghua University, Shanghai, P. R. China
In order to improve the moisture absorption, the antistatic properties of chemical fiber and improve the wearing comfort of fabric, the author has studied the modification and the production process of the sheath-core composite fiber which made of bio-based polyamide 56 and PET. Experiments show: selecting the appropriate production technology, using the bio-based polyamide 56 as the cortical structures, using the pet as the core structure we can produce high quality Sheath-core composite modified fiber by Composite spinneret. The Fiber has good moisture absorption performance and easy to be dyed. The fabric feel satiny soft and has a good elasticity, antistatic effect. It wears comfortable and the conformal performance is good.
The Research on the Production of Bio-based Polyamides 56 Sheath-core Composite Modified Fiber, International Journal of Materials Science and Applications.
Vol. 5, No. 2,
2016, pp. 79-83.
Weicai Yu. The analysis on Physical properties and spinnability of nylon 56 [J]: Polyester Industr, 2014(1), p. 38-39.
Jinyu Wang, Huaping Wang, Bimei Chen. The research on shrinkage behavior of Polyester polyamide composite fiber [J]: Synthetic fiber industry, 2002, 25(10): 18-21.
Weicai Yu. Physical properties and spinnability analysis of nylon 56 [J]: Polyester industry, 2014(1): 38-39.
Haifeng Yu, Meigui Yang. Discussion on PET/PTT compound fiber technology [J]: Synthetic Fiber, 2011, 34 (6): 53-55.
Morales-Gámez, L., D. Soto, L. Franco, and J. Puiggalí, Brill transition and melt crystallization of nylon 56: An odd–even polyamide with two hydrogen-bonding directions, Polymer, 2010, 51, (24), p. 5788-5798.
J.R.Araujo, C.B. Adamo, M.V. Costa e Silva, M.-A. De Paoli. Antistat ic-Reinforced Bioco mposites of Polyamide-6 and Polyaniline- Coated Curaua Fibers Prepared on a Pilot Plant Scale [J]. polymer compsites, 2013, 10(1002), p. 1081-1090.
Huang X, Li C, Guan G, et al. Crystallization kinetics, melting behavior, And morphologiesofpoly (butylenesuccinate) andpoly (butylenesuccinate)-block-poly (propylene glycol) segmented copolyester [J]. Journalof Applied polymer Science, 2010, 118(4): 2225-2235.
Samanta, S., J. He, S. Selvakumar, J. Lattimer, C. Ulven, M. Sibi, J. Bahr, and B.J. Chisholm, Polyamides based on the renewable monomer, 1,13-tridecane diamine II: Synthesis and characterization of nylon 13,6, Polymer, 2013, 54, (3), p. 1141-1149.
Study on preparation and performance of Nylon 6 / nano montmorillonite composite material [J].Synthetic fiber, 2013, 42(3), p. 1-6.
Yuan Zong. Preparation and Properties of Nano composite metal oxides/polyamide composite fiber [J]. Synthetic fiber, 2013, 42(3), p. 1-6.
Magill, J. H. Spherulitic Crystallization. Part I. “Odd-Even” Polyamides: Nylon 56 and Nylon 96, Journal of Polymer Science: Part A Vol. 965, 3, p. 1195-1219.
Berda E B, Foster E J, Meijer E W．Toward controlling folding in synthetic polymers: Fabricating and characterizing supramolecular single-chain nanoparticles [J]. Macromolecules, 2010, 43, p. 1430-1437.