Copolymerization-Regulated Hydrogen Bonds: A New Routine for High-Strength Copolyamide 6/66 Fibers

Hydrogen bond interactions are important for nylon fibers, which improve its mechanical properties and crystallization behavior, while hindering the movement and orientation of the molecular chain during the drawn process. In this study, hexamethylene adipamide was used as the second monomer in copolymerization with ε-caprolactam to obtain copolyamide 6/66 (CoPA), and high-tenacity fibers with a maximum value up to 8.0 cN/dtex were achieved by a multi-step drawn and thermal setting process. Results show that the hexamethylene–adipamide ratio affected the draw ratio (DR) of the as-spun fiber, on the tenacity of final high-performance fiber, and on crystalline. Both DR and tenacity showed evident increases with the hexamethylene–adipamide ratio up to 6% in CoPA and then changed smoothly. However, XRD and DSC results illustrate a decreased tendency with regard to crystallinity. The attenuated in-site total reflection Fourier transform infrared (ATR-FTIR) spectra were used to study the hydrogen bond interaction between the C=O group and N–H group and the crystal form of the fiber. Results show that the copolymerization destroyed the regularity of the main chain of CoPA and reduces the interaction of interstrand hydrogen bonds, facilitating the formation of the γ-crystalline form in as-spun fibers, fulfilling the transition from the γ to α crystalline form during the fiber-drawing step because of the release of the C=O group and N–H group from the hydrogen bond interaction at an elevated temperature close to the molten temperature of CoPA, and then reforming during the thermal-setting step which soiled the crystalline and improved the tenacity of the fiber. The copolymerization with a homologous monomer regulates the hydrogen bond interaction, fulfills the high drawn ratio and high tenacity fiber, and provides a new route for high-performance fiber preparation using traditional fiber formation of polymers.

[1]  T. Oh,et al.  Experimental and Molecular Dynamics Studies on Tensile Properties of Nylon 6/Graphene Composite Filaments , 2022, Fibers and Polymers.

[2]  S. Rwei,et al.  Synthesis and characterization of trace aromatic copolyamide 6 with tunable mechanical and viscoelastic behavior , 2021, Journal of Applied Polymer Science.

[3]  A. Schenning,et al.  Hydrogen-Bonded Supramolecular Liquid Crystal Polymers: Smart Materials with Stimuli-Responsive, Self-Healing, and Recyclable Properties , 2021, Chemical reviews.

[4]  H. Xiang,et al.  Molecular Weight Discrete Distribution-Induced Orientation of High-Strength Copolyamide Fibers: Effects of Component Proportion and Molecular Weight , 2021, Macromolecules.

[5]  A. Dawelbeit,et al.  Tentative Confinement of Ionic Liquids in Nylon 6 Fibers: A Bridge between Structural Developments and High-Performance Properties , 2021, ACS omega.

[6]  Dong-Hyun Kim,et al.  Effect of low melting temperature polyamide fiber-interlaced carbon fiber braid fabric on the mechanical performance and fracture toughness of CFRP laminates , 2020 .

[7]  T. Kikutani,et al.  Melt-Spun Fibers for Textile Applications , 2020, Materials.

[8]  S. Rwei,et al.  Synthesis and characterization of low-temperature polyamide 6 (PA6) copolyamides used as hot melt adhesives and derived from the comonomer of novel aliphatic diamine bis(2-aminoethyl) adipamide and adipic acid , 2020 .

[9]  B. Gibb The centenary (maybe) of the hydrogen bond , 2020, Nature Chemistry.

[10]  Haoran Ma,et al.  Biomass polyamide elastomers based on hydrogen bonds with rapid self-healing properties , 2020, European Polymer Journal.

[11]  Yi-Huan Lee,et al.  Effect of Bis (2-Aminoethyl) Adipamide/Adipic Acid Segment on Polyamide 6: Crystallization Kinetics Study , 2020, Polymers.

[12]  Yurong Yan,et al.  Melting behavior and non‐isothermal crystallization kinetics of copolyamide 6/12 , 2019, POLYMER CRYSTALLIZATION.

[13]  S. Borhani,et al.  Structure and properties of nylon-6/amino acid modified nanoclay composite fibers , 2019, The Journal of The Textile Institute.

[14]  Xun Pan,et al.  Controllable Crystallization Behavior of Nylon-6/66 Copolymers Based on Regulating Sequence Distribution , 2018, Industrial & Engineering Chemistry Research.

[15]  Yongjin Li,et al.  Ionic Liquids Incorporating Polyamide 6: Miscibility and Physical Properties , 2018, Polymers.

[16]  Tao Zhou,et al.  Two-step volume phase transition mechanism of poly(N-vinylcaprolactam) hydrogel online-tracked by two-dimensional correlation spectroscopy. , 2017, Physical chemistry chemical physics : PCCP.

[17]  Tao Zhou,et al.  Understanding the crystallization behavior of polyamide 6/polyamide 66 alloys from the perspective of hydrogen bonds: projection moving-window 2D correlation FTIR spectroscopy and the enthalpy , 2016 .

[18]  Xiaobo Hu,et al.  Weak Hydrogen Bonding Enables Hard, Strong, Tough, and Elastic Hydrogels , 2015, Advanced materials.

[19]  H. Avci,et al.  High‐performance filaments by melt spinning low viscosity nylon 6 using horizontal isothermal bath process , 2015 .

[20]  K. Shu,et al.  Preparation and Properties of Nylon 6/66 Copolymer with a Small Proportion of Hexamethylene Adipamide Salt , 2014 .

[21]  Cheng Yao,et al.  Thermal, physical and mechanical properties of hydrogenated dimer acid-based Nylon 636/Nylon 66 copolymers , 2013 .

[22]  R. Orlando,et al.  Ab initio calculation of the crystalline structure and IR spectrum of polymers: nylon 6 polymorphs. , 2012, The journal of physical chemistry. B.

[23]  Hyounil Yoon Melt Spinning of High Performance Poly(ethylene terephthalate) (PET) Multifilament Yarn via Utilizing a Horizontal Isothermal Bath (HIB) in the Threadline , 2012 .

[24]  R. Ruoff,et al.  Hydrogen bond networks in graphene oxide composite paper: structure and mechanical properties. , 2010, ACS nano.

[25]  D. Litchfield,et al.  The role of nanoclay in the generation of poly(ethylene terephthalate) fibers with improved modulus and tenacity , 2008 .

[26]  T. Hasegawa,et al.  High temperature zone-drawing of nylon 66 microfiber prepared by CO2 laser-thinning , 2006 .

[27]  N. Murthy,et al.  Hydrogen bonding, mobility, and structural transitions in aliphatic polyamides , 2006 .

[28]  William A. Goddard,et al.  Nylon 6 Crystal Structures, Folds, and Lamellae from Theory , 2002 .

[29]  Lixing Dai,et al.  Infrared Spectroscopic Investigation of Hydrogen Bonding in EVOH Containing PVA Fibers , 2002 .

[30]  T. Kanamoto,et al.  Effects of crystalline forms on the deformation behaviour of nylon-6 , 1998 .

[31]  T. Kunugi,et al.  Preparation of high-modulus nylon 6 fibers by vibrating hot drawing and zone annealing , 1998 .

[32]  A. Argon,et al.  Deformation resistance in oriented nylon 6 , 1992 .

[33]  H. Ishida,et al.  FTIR separation of nylon‐6 chain conformations: Clarification of the mesomorphous and γ‐crystalline phases , 1992 .

[34]  R. Stadler,et al.  New multiphase architecture from statistical copolymers by cooperative hydrogen bond formation , 1990 .

[35]  Paul C. Painter,et al.  Hydrogen bonding in polymers: infrared temperature studies of an amorphous polyamide , 1985 .

[36]  H. Starkweather,et al.  Hydrogen bonding in nylon 66 and model compounds , 1985 .

[37]  S. Cooper,et al.  Hydrogen bonding in polyamides , 1976 .

[38]  N. Vasanthan Polyamide fiber formation: structure, properties and characterization , 2009 .

[39]  S. Murase,et al.  Intrinsic Birefringence of γ-Form Crystal of Nylon 6: Application to Orientation Development in High-Speed Spun Fibers of Nylon 6 , 2001 .

[40]  M. Hirai,et al.  Crystal structure of the γ‐form of nylon 6 , 1965 .

[41]  Y. Kinoshita An investigation of the structures of polyamide series , 1959 .