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Xiao H, Shi MW, Liu LL. The Crystallinity and Orientation Structure and Crimp Properties of PET/PTT Bicomponent Filament. Advanced Materials Research 2013; 627(1): 110–116.XiaoHShiMWLiuLLThe Crystallinity and Orientation Structure and Crimp Properties of PET/PTT Bicomponent FilamentAdvanced Materials Research2013627111011610.4028/www.scientific.net/AMR.627.110Search in Google Scholar
Chen SH, Wang SY. Effect of Thermal Stimuli on Physical Behaviors of PET/PTT Bicomponent Filament. Advanced Materials Research 2010; 129–131: 280–284.ChenSHWangSYEffect of Thermal Stimuli on Physical Behaviors of PET/PTT Bicomponent FilamentAdvanced Materials Research2010129–13128028410.4028/www.scientific.net/AMR.129-131.280Search in Google Scholar
Yang ZL, Wang FM. Dyeing and finishing performance of different PTT/PET bi-component filament fabrics. Indian Journal of Fibre & Textile Research 2016; 41(4): 411–417.YangZLWangFMDyeing and finishing performance of different PTT/PET bi-component filament fabricsIndian Journal of Fibre & Textile Research2016414411417Search in Google Scholar
Chen SH, Wang SY. Tensile and Fracture Behaviors of PET/PTT Side-Side Bicomponent Filament. International Journal of Polymer Analysis and Characterization 2010; 15(3): 147–154.ChenSHWangSYTensile and Fracture Behaviors of PET/PTT Side-Side Bicomponent FilamentInternational Journal of Polymer Analysis and Characterization201015314715410.1080/10236660903585350Search in Google Scholar
Fang Y, Wang CH, Liang HF, Bao LL et al. Theoretical and experimental study on the crimp mechanism of bi-component filament. Advanced Materials Research 2012; 476–478(0): 2209–2212.FangYWangCHLiangHFBaoLLTheoretical and experimental study on the crimp mechanism of bi-component filamentAdvanced Materials Research2012476–47802209221210.4028/www.scientific.net/AMR.476-478.2209Search in Google Scholar
Oh TH. Effects of Spinning and Drawing Conditions on the Crimp Contraction of Side-by-Side Poly(trimethylene terephthalate) Bicomponent Fibers. Journal of Applied Polymer Science 2010; 102(2): 1322–1327.OhTHEffects of Spinning and Drawing Conditions on the Crimp Contraction of Side-by-Side Poly(trimethylene terephthalate) Bicomponent FibersJournal of Applied Polymer Science201010221322132710.1002/app.23988Search in Google Scholar
Oh TH. Melt Spinning and Drawing Process of PET Side-by-Side Bicomponent Fibers. Journal of Applied Polymer Science 2006; 101(3): 1362–1367.OhTHMelt Spinning and Drawing Process of PET Side-by-Side Bicomponent FibersJournal of Applied Polymer Science200610131362136710.1002/app.23287Search in Google Scholar
Lai K, Chen MY, Sun RJ et al. Study on the Crimp Property of PTT/PET Bicomponent Filament. Advanced Materials Research 2013; 781–784(0): 2680–2684.LaiKChenMYSunRJStudy on the Crimp Property of PTT/PET Bicomponent FilamentAdvanced Materials Research2013781–78402680268410.4028/www.scientific.net/AMR.781-784.2680Search in Google Scholar
Rwei SP, Lin YT, Su YY. Study of Self-Crimp Polyester Fibers. Polymer Engineering and Science 2005; 45(6): 838–845.RweiSPLinYTSuYYStudy of Self-Crimp Polyester FibersPolymer Engineering and Science200545683884510.1002/pen.20338Search in Google Scholar
Dention MJ. The Crimp Curvature of Bicomponent Fibers. Journal of the Textile Institute 1982; 73(6): 253–263.DentionMJThe Crimp Curvature of Bicomponent FibersJournal of the Textile Institute198273625326310.1080/00405008208631752Search in Google Scholar
Liu XS, Jiao SY, Wang FM. Configuring the spinning technology of PTT/PET bicomponent filaments according to fabric elasticity. Textile Research Journal 2013; 83(5): 487–498.LiuXSJiaoSYWangFMConfiguring the spinning technology of PTT/PET bicomponent filaments according to fabric elasticityTextile Research Journal201383548749810.1177/0040517512447584Search in Google Scholar
Luo J, Xu GB, Wang FM. External Configuration and Crimp Parameters of PTT (Polytrimethylene terephthalate)/PET (Polyethylene terephthalate) Conjugated Fiber. Fibers and Polymers 2009; 10(4): 508–512.LuoJXuGBWangFMExternal Configuration and Crimp Parameters of PTT (Polytrimethylene terephthalate)/PET (Polyethylene terephthalate) Conjugated FiberFibers and Polymers200910450851210.1007/s12221-009-0508-8Search in Google Scholar
Chuah HH. Orientation and Structure Development in Poly(trimethylene terephthalate) Tensile Drawing. Macromolecules 2001; 34(20): 6985–6993.ChuahHHOrientation and Structure Development in Poly(trimethylene terephthalate) Tensile DrawingMacromolecules200134206985699310.1021/ma010317zSearch in Google Scholar
Guo J, Zheng N, Chen YT. Study on Influence of Crimping Performance of PET/PTT Self-Crimp Yarn Treated with Moist Heat. Advanced Materials Research 2011; 287–290(0): 2547–2551.GuoJZhengNChenYTStudy on Influence of Crimping Performance of PET/PTT Self-Crimp Yarn Treated with Moist HeatAdvanced Materials Research2011287–29002547255110.4028/www.scientific.net/AMR.287-290.2547Search in Google Scholar
Chen SH, Wang SY. Latent-Crimp Behavior of PET/PTT Elastomultiester and a Concise Interpretation. Journal of Macromolecular Science, Part B: Physics. 2011; 50(7): 1447–1459.ChenSHWangSYLatent-Crimp Behavior of PET/PTT Elastomultiester and a Concise InterpretationJournal of Macromolecular Science, Part B: Physics20115071447145910.1080/00222348.2010.518879Search in Google Scholar
Jiang ZH, Guo ZG, Zhang ZQ. Preparation and properties of bottle-recycled polyethylene terephthalate (PET) filaments. Textil Research Journal 2018; 89(7): 1207–1214.JiangZHGuoZGZhangZQPreparation and properties of bottle-recycled polyethylene terephthalate (PET) filamentsTextil Research Journal20188971207121410.1177/0040517518767146Search in Google Scholar
Ayad E, Cayla AL, Rault F et al. Influence of Rheological and Thermal Properties of Polymers During Melt Spinning on Bicomponent Fiber Morphology. Journal of Materials Engineering and Performance 2016; 25(8): 3296–3302.AyadECaylaALRaultFInfluence of Rheological and Thermal Properties of Polymers During Melt Spinning on Bicomponent Fiber MorphologyJournal of Materials Engineering and Performance20162583296330210.1007/s11665-016-2193-2Search in Google Scholar
Petraccone V, Rosa CD, Guerra G et al. On the Double Peak Shape of Melting Endotherms of Isothermally Crystallized Isotactic Polypropylene Samples. Die Makromolekulare Chemie Rapid Communications 1984; 5(10): 631.PetracconeVRosaCDGuerraGOn the Double Peak Shape of Melting Endotherms of Isothermally Crystallized Isotactic Polypropylene SamplesDie Makromolekulare Chemie Rapid Communications198451063110.1002/marc.1984.030051003Search in Google Scholar
Wang Y, Sun YM, Zhu ZY et al. XRD Study of PET Irradiated by 1.158 GeV Fe Ions. IMP and GIRFL Annual Report 2002; (1): 63.WangYSunYMZhuZYXRD Study of PET Irradiated by 1.158 GeV Fe IonsIMP and GIRFL Annual Report2002163Search in Google Scholar
Hu JC, Yang D, Chen P et al. Studies on The Crystallinity of PET by WAXD. Acta Polymerica Sinica 1990; (3): 283.HuJCYangDChenPStudies on The Crystallinity of PET by WAXDActa Polymerica Sinica19903283Search in Google Scholar
Ren MQ, Zhang ZY, Wu SZ et al. Uniaxial Orientation and Crystallization Behavior of Amorphous Poly (ethylene terephthalate) Fibers. Journal of Polymer Research 2006; 13(1): 9–15.RenMQZhangZYWuSZUniaxial Orientation and Crystallization Behavior of Amorphous Poly (ethylene terephthalate) FibersJournal of Polymer Research200613191510.1007/s10965-005-9005-ySearch in Google Scholar
Mehdi Z, Mojtaba S. Isothermal Crystallization Kinetics of Poly(Ethylene Terephthalate)S of Different Molecular Weights. Journal of the Iranian Chemical Society 2013; 10(1): 77–84.MehdiZMojtabaSIsothermal Crystallization Kinetics of Poly(Ethylene Terephthalate)S of Different Molecular WeightsJournal of the Iranian Chemical Society2013101778410.1007/s13738-012-0148-6Search in Google Scholar
Zhu PP, Ma DZ. Study on the Double Cold Crystallization Peaks of Poly (Ethylene Terephthalate) (PET): 2. Samples Isothermally Crystallized At High Temperature. European Polymer Journal 1999; 35(4): 739–742.ZhuPPMaDZStudy on the Double Cold Crystallization Peaks of Poly (Ethylene Terephthalate) (PET): 2. Samples Isothermally Crystallized At High TemperatureEuropean Polymer Journal199935473974210.1016/S0014-3057(98)00179-7Search in Google Scholar
Xiao H, Shi MW, Liu LL et al. The Structures and Properties of PET (Polyethylene Terephthalate)/PTT (Polytrimethylene Terephthalate) Self-Crimp Filament at Different Temperatures. Advanced Materials Research 2011; 332–334(0): 239–245.XiaoHShiMWLiuLLThe Structures and Properties of PET (Polyethylene Terephthalate)/PTT (Polytrimethylene Terephthalate) Self-Crimp Filament at Different TemperaturesAdvanced Materials Research2011332–334023924510.4028/www.scientific.net/AMR.332-334.239Search in Google Scholar
Wu AH, Xu GP, Luo GH et al. Study of the Mechanical Properties and Releasing Anion Capacity of Anionic Functional PET Fiber. Applied Mechanics and Material 2013; 423–426(0): 322–325.WuAHXuGPLuoGHStudy of the Mechanical Properties and Releasing Anion Capacity of Anionic Functional PET FiberApplied Mechanics and Material2013423–426032232510.4028/www.scientific.net/AMM.423-426.322Search in Google Scholar
Zhang X, Tian XY, Yao XY et al. Isothermal and Non-Isothermal Shrinkage Behaviors of Highly Oriented PET Yarns. Fibers and Polymers 2008; 9(3): 360–364.ZhangXTianXYYaoXYIsothermal and Non-Isothermal Shrinkage Behaviors of Highly Oriented PET YarnsFibers and Polymers20089336036410.1007/s12221-008-0058-5Search in Google Scholar
Rim PB, Nelson CJ. Properties of PET Fibers with High Modulus and Low Shrinkage (HMLS). I. Yarn Properties and Morphology. Applied Polymer. Sci. 2010; 42(7): 1807–1813.RimPBNelsonCJProperties of PET Fibers with High Modulus and Low Shrinkage (HMLS). I. Yarn Properties and MorphologyApplied Polymer. Sci.20104271807181310.1002/app.1991.070420702Search in Google Scholar