Modelling contraction flows of bi-disperse polymer blends using the Rolie-Poly and Rolie-Double-Poly equations

Adila A. Azahar; Oliver G. Harlen; Mark A. Walkley

Korea-Australia Rheology Journal, Vol.31, No.4, 203-209, November, 2019

DOI10.1007/s13367-019-0021-6 Export Citation

Modelling contraction flows of bi-disperse polymer blends using the Rolie-Poly and Rolie-Double-Poly equations

Adila A. Azahar^{1, 2}, Oliver G. Harlen^{3, †}, and Mark A. Walkley¹

¹School of Computing, University of Leeds, Leeds LS2 9JT, UK
²School of Mathematical Sciences, Universiti Sains Malaysia, Penang 11800 USM, Malaysia
³School of Mathematics, University of Leeds, Leeds LS2 9JT, UK

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The flow of a bi-disperse polymer melt through a hyperbolic contraction is simulated using the recently proposed Rolie-Double-Poly constitutive model (Boudara et al., 2019). This simplified tube model takes account of the nonlinear coupling between the dynamics of the long and short-chains in a bi-disperse blend, in particular it reproduces the enhancement of the stretch relaxation time that arises from the coupling between constraint release and chain retraction. Flow calculations are performed by implementing both the Rolie-Double-Poly and multimode Rolie-Poly models in OpenFOAM® using the RheolTool library. While both models predict very similar flow patterns, the enhanced stretch relaxation of the Rolie-Double-Poly models results in an increase in the molecular stretch of the long chain component in the pure extensional flow along the centre-line of the contraction, but a decrease in the stretch in shear-flow near the channel walls.

Keywords:polymer melts;extensional flow;contraction flows;Rolie-Poly model;OpenFOAM

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[2] Boudara VAH, Peterson JD, Leal LG, Read DJ, J. Rheol., 63(1), 71 (2019)

[3] Collier JR, Romanoschi O, Petrovan S, J. Appl. Polym. Sci., 69(12), 2357 (1998)

[4] Collis MW, Lele AK, Mackley MR, Graham RS, Groves DJ, Likhtman AE, Nicholson TM, Harlen OG, McLeish TCB, Hutchings LR, Fernyhough CM, Young RN, J. Rheol., 49(2), 501 (2005)

[5] de Gennes PG, J. Chem. Phys., 55, 572 (1971)

[6] des Cloizeaux J, Europhys. Lett., 5, 437 (1988)

[7] Doi M, Edwards SF, The Theory of Polymer Dynamics, 1986.

[8] Graham RS, Likhtman AE, McLeish TCB, J. Rheol., 47(5), 1171 (2003)

[9] James DF, Chandler GM, Armour SJ, J. Non-Newton. Fluid Mech., 35, 421 (1990)

[10] Likhtman AE, Graham RS, J. Non-Newton. Fluid Mech., 114, 112 (2003)

[11] Lord TD, Scelsi L, Hassell DG, Mackley MR, Embery J, Auhl D, Harlen OG, Tenchev R, Jimack PK, Walkley MA, J. Rheol., 54(2), 355 (2010)

[12] Pimenta F, Alves MA, J. Non-Newton. Fluid Mech., 239, 85 (2017)

[13] Read DJ, Jagannathan K, Sukumaran SK, Auhl D, J. Rheol., 56(4), 823 (2012)

[14] Tenchev R, Gough T, Harlen OG, Jimack PK, Klein DH, Walkley MA, J. Non-Newton. Fluid Mech., 166(5-6), 307 (2011)

[15] Weller HG, Tabor G, Jasak H, Fureby C, Comput. Phys., 12, 620 (1998)