High-speed fiber spinning process with spinline flow-induced crystallization and neck-like deformation

Rheologica Acta

Volumn 45, Issue 5, 2006, Pages 575-582

  Shin, Dong Myeong ^a   Lee, Joo Sung ^a   Jung, Hyun Wook ^a   Hyun, Jae Chun ^a  

^a Korea University   (South Korea)

Author keywords

Apparent extensional viscosity; Flow induced crystallization; High speed fiber spinning; Neck like deformation; Stability

Indexed keywords

COMPUTER SIMULATION; CRYSTALLIZATION; DEFORMATION; MATHEMATICAL MODELS; SPINNING (FIBERS); VISCOSITY;

EID: 33745842185     PISSN: 00354511     EISSN: None     Source Type: Journal    
DOI: 10.1007/s00397-006-0100-8     Document Type: Article

References (21)

1. Chen S, Yu W, Spruiell JE (1987) Structure and properties of high-speed melt-spun filaments of poly (butylene terephthalate). J Appl Polym Sci 34:1477-1492
2. Doufas AK, McHugh AJ, Miller C (2000a) Simulation of melt spinning including flow-induced crystallization - part I. Model development and predictions. J Non-Newton Fluid Mech 92:27-66
3. Doufas AK, McHugh AJ, Miller C, Immaneni A (2000b) Simulation of melt spinning including flow-induced crystallization - part II. Quantitative comparisons with industrial spinline data. J Non-Newton Fluid Mech 92:81-103
4. Fisher RJ, Denn MM (1976) Theory of isothermal melt spinning and draw resonance. AIChE J 22:236-241
5. Gelder D (1971) Stability of fiber drawing processes. Ind Eng Chem Fundam 10:534-535
6. Haberkorn H, Hahn K, Breuer H, Dorrer HD, Matthies P (1993) On the neck-like deformation in high-speed spun polyamides. J Appl Polym Sci 47:1555-1579
7. Joo YL, Sun J, Smith MD, Armstrong RC, Brown RA, Ross RA (2002) Two-dimensional numerical analysis of non-isothermal melt spinning with and without phase transition. J Non-Newton Fluid Mech 102:37-70
8. Jung HW, Song HS, Hyun JC (1999) Analysis of the stabilizing effect of spinline cooling in melt spinning. J Non-Newton Fluid Mech 87:165-174
9. Kikutani T, Morinaga H, Takaku A, Shimizu J (1990) Effect of spinline quenching on structure development in high-speed melt spinning of PET - diameter profiles in the spinline. Int Polym Process 5:20-24
10. Kohler WH, Shrikhande P, McHugh AJ (2005) Modeling melt spinning of PLA fibers. J Macromol Sci Phys 44:185-202
11. Kulkarni JA, Beris AN (1998) A model for the necking phenomenon in high-speed fiber spinning based on flow-induced crystallization. J Rheol 42:971-994
12. Lee JS, Shin DM, Jung HW, Hyun JC (2005) Transient solutions of the dynamics in low-speed fiber spinning process accompanied by flow-induced crystallization. J Non-Newton Fluid Mech 130:110-116
13. Muslet IA, Kamal MR (2004) Computer simulation of the film blowing process incorporating crystallization and viscoelasticity. J Rheol 48:525-550
14. Patel RM, Bheda JH, Spruiell JE (1991) Dynamics and structure development during high-speed melt spinning of nylon-6-2. Mathematical modeling. J Appl Polym Sci 42:1671-1682
15. Phan-Thien N (1978) A nonlinear network viscoelastic model. J Rheol 22:259-283
16. Raghavan JS, Cuculo JA (1999) Analysis of necking in high-speed spinning. J Polym Sci B Polym Phys 37:1565-1573
17. Shin DM, Lee JS, Jung HW, Hyun JC (2005) Analysis of the effect of flow-induced crystallization on the stability of low-speed spinning using the linear stability method. Kor Aust Rheol J 17:63-69
18. Takarada W, Kazama K, Ito H, Kikutani T (2004) High-speed melt spinning of polyethylene terephthalate with periodic oscillation of take-up velocity. Int Polym Process 19:380-387
19. Ziabicki A (1976) Fundamentals of fibre formation. Wiley-Interscience, New York
20. Ziabicki A (1988) The mechanisms of neck-like deformation in high-sped melt spinning - 1. Rheological and dynamics factors. J Non-Newton Fluid Mech 30:141-155
21. Ziabicki A, Kawai H (1985) High-speed fiber spinning. Wiley, New York