Sage Journals: Discover world-class research

Abstract

The melt viscoelastic properties of a low-density polyethylene (LDPE) are measured, at temperatures varying from 140°C to 170°C and in a wide range of extrusion rates by means of a capillary rheometer, to identify the influence of extrusion conditions (such as temperature, die diameter, and flow rate) on the melt viscoelastic behavior. The results show that the entry pressure drop (▵P_en) and the melt extension stress are a quadric function of extrusion rate (V), and it decreases with an increase in die diameter (d). Similarly, the die-swell ratio (B) increases nonlinearly with increasing V and shear stress at the channel wall. The dependence of B on temperature corresponds approximately with the Arrhenius expression. Under these experimental conditions, the ▵P_en and B increase roughly as an exponential function with an increase in the channel contraction ratio.

Keywords

LDPE capillary extrusion melt viscoelasticity.

References

Briassoulis, D. (2005). The Effects of Tensile Stress and the Agrochemical Vapam on the Ageing of Low Density Polyethylene (LDPE) Agricultural Films. Part I. Mechanical Behaviour. Polym. Degrad. Stabil., 88(11): 489-503.

La Mantia, F.P. , Scaffaro, R. , Carianni, G. and Mariani, P. (2005). Rheological Properties of Different Film Blowing Polyethylene Samples Under Shear and Elongation Flow, Macromol. Mater. Eng., 290(3): 159-164.

Liang, J.Z. and Ness, J.N. (1997). Studies on Melt Flow Properties of Low Density and Linear Low Density Polyethylene Blends in Capillary Extrusion, Polymer Testing, 16: 173-184.

Rasussen, H.K. , Nielsen, J.K. , Bach, A. and Hassager, O. (2005). Viscosity Overshoot in the Start-up of Uniaxial Elongation of Low Density Polyethylene Melts, J. Rheol., 49(2): 369-381.

Drozdov, A.D. , Agarwal, S. and Gupta, P.A. (2005). The Effect of Temperature on the Viscoelastic Response of Polymer Melts, Int. J. Eng. Sci., 43(3-4): 304-320.

Liang, J.Z. , Huang, Y.Q. , Tang, G.J. and Ness, J.N. (1992). A Study of the Flow Behaviour of Rubber Compound Melt through Extrusion die with Different Entry Angles, Plast. Rubber Compos. Process. Appl., 18: 311-315.

Wong, A.C.Y. and Jiang, L. (2001). Study on the Melt Entry Flow Characteristics in Axisymmetric Dies with Abrupt Contraction by a Visualization Technique, Polym . Test., 20(8): 861-867.

Sombatsompop, N. and Intawong, N.T. (2001). Flow Properties and Entrance Corrections of Polymer Melts by a Mobile Barrel Capillary Rheometer, Polym. Test., 20(1): 97-103.

Sombatsompop, N. and Intawong, N.T. (1999). A Novel Capillary Rheometer for Measurement of flow Properties of Polymer Melts, Mater. Res. Inno., 3(3): 150-155.

10.

Bagley, E.B. (1957). End Corrections in the Capillary Flow of Polyethylene , J. Appl. Phys., 28: 624-627.

11.

Liang, J.Z. (2002). Melt Rheology of Nanometre-calcium-Carbonate-filled Acrylonitrile-butadiene-styrene (ABS) Copolymer Composites During Capillary Extrusion, Polym. Int., 51: 1473-1478.

12.

Liang, J.Z. (2005). Estimation of Entry Natural Converging Angles During Capillary Extrusion Flow of Carbon Black Filled NR/SBR Compound, Polym . Test., 24(4): 435-438.

13.

Liang, J.Z. (2006). Quantitative Characterization of Viscoelastic Properties and Their Relationship During Extrusion Flow of Polymer Melts, Polym. Plast. Technol. Eng., 45: 329-334.

14.

Liang, J.Z. (1991). Research into Polymer Melt Die Swell During Extrusion, Plast. Rubber Compos. Process. Appl., 15: 75-77.

Effects of Extrusion Conditions on Melt Viscoelasticity during Capillary Flow of Low-Density Polyethylene

Abstract

Keywords

References