The experimental design and optimization of twin-screw extruders (TSE) is often very expensive and time consuming. Three-dimensional, numerical process simulation is therefore of great importance for future technological progress in the plastics industry. It allows a wide variety of configurations to be analyzed and virtually optimized in a resource-efficient manner in a very short time and at low cost. Although there have already been promising developments and research activities in this field in recent years, the three-dimensional simulation of TSE remains a major challenge today. This is particularly due to the fact that moving, interlocking elements cannot easily be calculated by classical, body-fitted simulations. The continuous development of computer technology is accompanied by the development of new, powerful simulation methods. For example, the Immersed Boundary Method is a very promising simulation method for overcoming current limitations in the simulation of interlocking, moving elements. Therefore, the aim of this research project is the development and validation of a novel IBM solver in OpenFOAM for the three-dimensional simulation of single-phase flows in a TSE. The new solver is to be validated on the one hand within a controlled laboratory experiment by a novel measuring device and on the other hand on a real TSE as a scale-up to real process conditions for the first time. The results of this research project represent a further step towards computer-aided design and can be used in future to simulate various TSE configurations. Due to the complexity of the simulation, this has not been possible or only in a simplified way still today. Furthermore, this research project will pave the way for the future development of a coupled flow solver, which covers both solid particles in terms of the Discrete Element Method (DEM) and a flow simulation using a suitable IBM solver. Such a coupled CFD-DEM simulation is essential in order to map the melting process during extrusion and thus simulate all process zones of the TSE together in the future.

DFG Programme Research Grants

International Connection Austria

Partner Organisation Fonds zur Förderung der wissenschaftlichen Forschung (FWF)

Cooperation Partner Dr. Christoph Goniva