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Numerical Analysis and Evaluation of Process and Geometry Specific Transient Temperature Fields for a New Variation of Gas-Assisted Injection Molding

  • E. Moritzer and S. Seidel
Published/Copyright: May 5, 2015
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International Polymer Processing
From the journal International Polymer Processing Volume 30 Issue 2

Abstract

Two-Stage GITBlow, a special injection molding process developed by Polymer Processing Paderborn, combines the advantages of gas-assisted injection molding and blow molding. This is achieved by producing a preform with gas-assisted injection molding, which is then inflated into a larger cavity in the same mold. The inflation behavior is heavily influenced by the temperature distribution over the cross section of the preform. The preform is not rotationally symmetric and features functional geometries that are not inflated during the second process stage. Therefore, the temperature development during the first stage, i.e. the gas-assisted injection molding, as well as cooling and handling of the preform, is essential for the subsequent inflation. If certain thermal conditions are met, inflation and the creation of a homogeneous wall thickness is improved. The development of the necessary temperature profiles for homogeneous inflation is heavily dependent on the geometry of the gas chamber. Due to the preform's geometry, characteristic material accumulations are formed during the gas injection. These create local temperature hotspots that act as heat sources during the temperature equalization before inflation starts. Simulations were conducted to predict the gas chamber geometry and its influence on the temperature distribution and development during the process. The combination of two different simulation approaches creates a new method to analyze GITBlow and similar processes. Simulation results were verified with extensive experimental studies.

* Mail address: Stefan Seidel, Polymer Processing Institute, University of Paderborn, Warburgerstr. 100, 33098 Paderborn, Germany, E-mail:

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Received: 2014-08-25
Accepted: 2014-11-08
Published Online: 2015-05-05
Published in Print: 2015-05-29

© 2015, Carl Hanser Verlag, Munich

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https://doi.org/10.3139/217.3010

Articles in the same Issue

  1. Contents
  2. Contents
  3. Regular Contributed Articles
  4. Multilayer Coextrusion of Polymer Composites to Develop Organic Capacitors
  5. Heat Flow Analysis and Efficiency Optimization of Rotational Molding Equipment for Large Plastic Products
  6. Thermorheology of Polyethylene Wax Modified Sulfur Asphalt
  7. Thermoplastic Cellulose Stearate and Cellulose Laurate: Melt Rheology, Processing and Application Potential
  8. Crystallization Kinetics for PP/EPDM/Nano-CaCO3 Composites – The Influence of Nanoparticles Distribution
  9. The Effect of ZnO Nanoparticle Filler on the Attenuation of ZnO/PCL Nanocomposites Using Microstrip Line at Microwave Frequency
  10. Synthesis and Properties of Nitrogen Heterocycle-Functionalized Core-Shell Hyperbranched Polyester
  11. Morphology Tuning of Conducting Polyaniline via Static, Liquid-Liquid Interfacial Polymerization Process and its Application for Optical pH Sensing
  12. Tuning of Final Performances of Soybean Oil–Based Polymer Nanocomposites: Effect of Styryl/Oil Functionalized Intercalant of Montmorillonite Reinforcer
  13. Processability, Thermal and Mechanical Properties of Rigid PVC/Kaolin Coated with Liquid Macromolecular Modifier Composites
  14. Numerical Analysis and Evaluation of Process and Geometry Specific Transient Temperature Fields for a New Variation of Gas-Assisted Injection Molding
  15. Effect of Feeding Strategy on the Properties of PP/Recycled EPDM Blends
  16. Analysis of a Single Screw Extruder with a Grooved Plasticating Barrel – Part I: The Melting Model
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