Experimental investigation and numerical simulation of liquid supported stretch blow molding

Zimmer, Johannes; Chauvin, G.; Stommel, Markus

doi:10.1002/pen.23961

Cited by 9 publications

(10 citation statements)

References 58 publications

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“…iii. Zimmer et al 11 managed numerical simulation of the liquid-forming process (LF). The internal pressure in the bottle is due to the liquid devoted.…”

Section: Through the Recent Work Bymentioning

confidence: 99%

“…1,[7][8][9][10] As a consequence, the mechanical behavior of PET, which is strongly related to the microstructural morphology of the material changes: rigidity or strength are multiplied by two or three in regard of the characteristics of the preform. 9 Many researches [1][2][3][4][5][6][11][12][13][14][15][16][17][18][19] have been carried out to capture the PET behavior during the SBM process: the experimental research 2,[11][12][13] provides the data to assess the accuracy of the numerical simulation. [14][15][16][17][18][19] Understating the mechanical performance of bottle by an experimental approach is of high-cost and decreases the productivity.…”

Section: Introduction: State Of Art On Isbm Modelingmentioning

confidence: 99%

“…Recently, Stephen et al 20 applied the meshfree method to simulate the SBM process. This method can lead to a stable and accurate numerical solution for SBM process. Zimmer et al 11 managed numerical simulation of the liquid‐forming process (LF). The internal pressure in the bottle is due to the liquid devoted. In SBM process, viscous dissipation during elongation has an effect on the evolution of the temperature and this phenomena call “self‐heating” needs to be taken into account in order to predict accurately the temperature distribution 18 .…”

Section: Introduction: State Of Art On Isbm Modelingmentioning

confidence: 99%

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In situ adjustment of a visco hyper elastic model for stretch blow molding process simulation of poly‐ethylene terephthalate bottles

Luo,

Tantchou Yakam,

Charlot

et al. 2023

Polymer Engineering & Sci

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Simulation of the stretch blow molding (SBM) process necessitates to develop a model able to reproduce the material behavior at high strain rate, large deformation with temperature gradient. On the other hand, both the need to understand polyethylene terephthalate (PET) material characteristics and the final bottle performance requirements continue to get higher. That necessitates a regular update of the identification of the model. Bottle producers are interested by managing this identification without a specific complex apparatus not available in an industrial context. The work presented here describes an in‐situ adjustment process for upgrading all parameters of a visco‐hyperelastic (VHE) model from a small number of blowing tests that do not necessitate complex equipment. The accuracy of the adjustment process is validated through the ability of the updated VHE model to reproduce the final shape, the pressure evolution and the tension of the rod during an industrial blowing of PET bottles.

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“…iii. Zimmer et al 11 managed numerical simulation of the liquid-forming process (LF). The internal pressure in the bottle is due to the liquid devoted.…”

Section: Through the Recent Work Bymentioning

confidence: 99%

Section: Introduction: State Of Art On Isbm Modelingmentioning

confidence: 99%

Section: Introduction: State Of Art On Isbm Modelingmentioning

confidence: 99%

See 1 more Smart Citation

In situ adjustment of a visco hyper elastic model for stretch blow molding process simulation of poly‐ethylene terephthalate bottles

Luo,

Tantchou Yakam,

Charlot

et al. 2023

Polymer Engineering & Sci

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show abstract

“…However, the presence of liquid as the forming medium introduces additional considerations; due to the increased density of the forming fluid versus air, gravity and inertial forces on the preform are no longer negligible, illustrated by Zimmer et al [3] in a numerical and experimental mechanical study. Heat transfer is also potentially increased, for if convection is considered to be the primary mode of heat transfer at the inner surface of the preform, liquid flowing over a solid has a much greater heat transfer coefficient than air.…”

Section: Background and Motivationmentioning

confidence: 99%

Numerical modelling of heat transfer in a cavity due to liquid jet impingement for liquid supported stretch blow moulding

Smyth

Menary

Geron

2018

AIP Conference Proceedings

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Impingement of a liquid jet in a polymer cavity has been modelled numerically in this study. Liquid supported stretch blow moulding is a nascent polymer forming process using liquid as the forming medium to produce plastic bottles. The process derives from the conventional stretch blow moulding process which uses compressed air to deform the preform. Heat transfer away from the preform greatly increases when a liquid instead of a gas is flowing over a solid; in the blow moulding process the temperature of the preform is tightly controlled to achieve optimum forming conditions. A model was developed with Computational Fluid Dynamics code ANSYS Fluent which allows the extent of heat transfer between the incoming liquid and the solid preform to be determined in the initial transient stage, where a liquid jet enters an air filled preform. With this data, an approximation of the extent of cooling through the preform wall can be determined.

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“…This method is used in polymer processing primarily for measuring the temperature of both finished parts and processing tools [3,6,9,15,19]. The measurements were made using the V-20 II ER005-10 infrared camera from VIGO System S.A. and the Therm V 20 software.…”

Section: Test Standmentioning

confidence: 99%

The Effect of Selected Conditions in a Thermoforming Process on Wall Thickness Variations

Sasimowski¹

2017

Adv. Sci. Technol. Res. J.

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The paper reports the results of a study on the effect of selected conditions in a thermoforming process for thin polystyrene sheet by vacuum assisted drape forming on the wall thickness non-uniformity of finished parts. The investigation was performed using Statistica's DOE module for three variables: temperatures in the external and internal zones of the heater as well as heating time of the plastic sheet. The results demonstrate that the wall thickness in the finished parts at the measuring points is primarily affected by the heating time and the temperature in the internal zone of the heater, while the temperature in the external zone only affects some regions of the finished part. The results demonstrate that a short heating time, and hence, a lower temperature of the plastic sheet lead to a more uniform deformation of both the bottom and the side walls of the finished part, and as a consequence, to smaller variations in the wall thickness. Shortening the heating time is, however, limited by the necessity of accurate reproduction of the shape of the finished part.

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Experimental investigation and numerical simulation of liquid supported stretch blow molding

Cited by 9 publications

References 58 publications

In situ adjustment of a visco hyper elastic model for stretch blow molding process simulation of poly‐ethylene terephthalate bottles

In situ adjustment of a visco hyper elastic model for stretch blow molding process simulation of poly‐ethylene terephthalate bottles

Numerical modelling of heat transfer in a cavity due to liquid jet impingement for liquid supported stretch blow moulding

The Effect of Selected Conditions in a Thermoforming Process on Wall Thickness Variations

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