Numerical Investigation of Gas Entrapment in Polymer Filling Process

doi:10.19596/j.cnki.1001-246x.8327

Abstract

Abstract:

The complicated gas entrapment problem in polymer filling process is studied. The moving melt interface is captured with a level set method. An XPP (eXtended Pom-Pom) constitutive model is utilized for the description of viscoelastic fluid. The governing equations of flow field are solved with a coupled continuous and discontinuous Galerkin method. The XPP constitutive equation, level set and its re-initialization equations are solved with an implicit discontinuous Galerkin method. Good agreement between experimental and numerical results illustrates validity of the combined algorithm. Influence of injection velocity and gate size on gas entrapment in a cavity with irregular insert was investigated. Entrapped gas is easier to appear as the injection velocity is higher and the gate size is smaller.

Key words: gas entrapment, finite element, discontinuous Galerkin, XPP constitutive model, level set method

CLC Number:

O242.1

Puyang GAO. Numerical Investigation of Gas Entrapment in Polymer Filling Process[J]. Chinese Journal of Computational Physics, 2021, 38(6): 693-706.

Figures/Tables 20

Fig.1 A schematic of irregular channel cavity

Fig.2 Mesh2 used in the computation

Fig.3 A comparison of experimental (left) and numerical (right) results at different time instants (a) t=2.48, (b) t=3.0, (c) t=3.4, (d) t=3.7

Fig.4 Interface front at t=2.48 on different meshes

Fig.5 (a) τxx, (b) τxy, (c) τyy along a vertical line x=7.5 on different meshes at t=3.7

Fig.6 A schematic of rectangular cavity with a diamond insert

Fig.7 Experimental (left) and numerical (right) results (a) t=0.4; (b) t=0.7; (c) t=1.1; (d) t=1.33

Fig.8 A schematic of trapezoidal cavity with an irregular insert

Fig.9 Mesh2 used in the computation

Fig.10 Profiles of interface front with u=2.0 at different time (a) t=0.2; (b) t=0.7; (c) t=1.0; (d) t=1.15

Fig.11 (a) Profiles of interface front and (b) τxx, (c) τxy, (d) τyy at t=0.7 on different meshes

Fig.12 Profiles of interface front with u=10 at different time (a) t=0.09; (b) t=0.15; (c) t=0.19; (d) t=0.28

Table 1 The minimum and maximum of τxx, τxy, τyy for a injection gate with middle size

	τ_xx		τ_xy		τ_yy
	最小值	最大值	最小值	最大值	最小值	最大值
u=2	-1.8	2.3	-2.1	2.1	-0.95	-0.92
u=5	-3.7	5.9	-4.7	4.7	-3.1	2.4
u=10	-4.1	6.7	-5.3	5.3	-3.4	3.9

Fig.13 The development of interface front with u=2.0 at (a) t=0.3; (b) t=1.5; (c) t=2.0; (d) t=2.5

Fig.14 Free surfaces for u=5.0 at different time instants (a) t=0.3; (b) t=0.6; (c) t=0.8; (d) t=1.1

Fig.15 The development of melt front with u=10.0 at (a) t=0.05; (b) t=0.15; (c) t=0.2; (d) t=0.3

Table 2 The minimum and maximum of τxx, τxy, τyy for a smaller injection gate

	τ_xx		τ_xy		τ_yy
	最小值	最大值	最小值	最大值	最小值	最大值
u=2	-1.9	2.2	-1.8	1.8	-0.86	1.1
u=5	-2.7	4.1	-4.7	4.7	-2.6	2.3
u=10	-3.7	5.7	-5.4	5.4	-2.9	2.7

Fig.16 Profiles of melt front with u=5.0 at four time instants (a) t=0.08; (b) t=0.18; (c) t=0.25; (d) t=0.4

Fig.17 Profiles of interface front with u=10.0 at different time instants (a) t=0.05; (b) t=0.1; (c) t=0.15; (d) t=0.25

Table 3 The minimum and maximum of τxx, τxy, τyy for a bigger injection gate

	τ_xx		τ_xy		τ_yy
	最小值	最大值	最小值	最大值	最小值	最大值
u=2	-1.7	2.8	-4.8	4.8	-0.95	1.05
u=5	-5.1	6.1	-6.3	6.3	-3.0	3.9
u=10	-5.6	6.2	-7.0	7.0	-4.1	4.6

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