Process Simulation and Material Modelling
The IBF carries out process simulations for a wide range of forming processes. Entire process chains can be simulated and effects on various scales can be taken into account. The range extends from macroscopic effects, such as the component geometry to surface structures and the microstructure of the material.
The process simulations can be used, for example, for process design and optimization in the areas of sheet metal forming and bulk metal forming. In combination with suitable material models, it is also possible to predict the microstructure evolution.
For process simulation, the IBF uses a wide range of both academic and industrially used software packages and also develops own software.
Simulation Sheet Metal FormingIBF
In the field of sheet metal forming we carry out process simulations mainly with the finite element programs Abaqus, LS-Dyna and Autoform.
Validated simulation models are available for stretch forming, deep drawing, bending and incremental sheet metal forming. If required, suitable models can be developed for other processes.
For further information, please contact the management of the research group Sheet Metal Forming.
Simulation Bulk Metal FormingIBF
In the field of bulk metal forming, process simulations are carried out with the finite element programs Abaqus, Simufact, Deform and Forge. Validated simulation models are available for open-die forging, ring rolling, flat rolling, roll bonding and caliber rolling. If required, suitable models can be developed for other processes.
For further information on the simulation of open-die forging and ring rolling, please contact the manager of the research group Bulk Metal Forming. For the simulation of flat rolling, roll bonding and caliber rolling, please contact the manager of the reserach group Flat and Long Products.
Microstructure Simulation With StrucSim
StrucSim is a program developed at the institute of metal forming to predict the microstructure evolution as well as the flow stress for hot forming processes. The challenge in hot forming processes, especially in multi-stage hot forming processes (process chains), is the description of the interaction between hardening and softening of the material. To overcome this challenge, the microstructure of the material is described by state variables, which develop depending on the process parameters (temperature, time etc.). Thus, quantities as the mean grain size or the recrystallized fraction can be calculated, and the flow stress can be derived for each time point. StrucSim is successfully used in several industrial and scientific projects. The extension of the functionality of the program, as well as the coupling to FE programs, such as Simufact, Abaqus etc. are ongoing work.
For further information, please contact Rajeevan Rabindran.
Image: Simulation of flow stress with StrucSim, Copyright: IBF
Fast Process Models for Rolling
Fast process models enable the accurate simulation of heavy plate rolling on the industrial and laboratory scale. Based on the pass schedule and material parameters it predicts the most important properties, such as force, temperature and microstructure, within seconds. Thus it has a wide range of applications, particularly in the field of design and optimization. With Industry 4.0 in mind, it has been coupled to a data base of industrial trials resulting in the ability to determine material parameters from just the measured forces. It has furthermore been coupled with machine learning algorithms to automatically design pass schedules. Fast process models are also being used for teaching and seminars, supplemented by a specially created graphical user interface. It allows students and seminar participants to develop an intuitive approach to the design, calculation and optimization of pass schedule as well as a detailed understanding of the underlying mechanisms.
For further information, please contact Alexander Krämer.
Image: Single pass during rolling including force, temperature and microstructure evolution, Copyright: IBF
STOFF - Fast Calculation Models for Open-Die Forging
Open-die forging is an incremental forming process, where the initial ingot is forged in up to many hundred forming steps towards the final geometry. The design of new forging process is mainly realized based upon experience or simple geometric correlations. However, by this only a simple geometrical-based process design is possible which does not give any statement about the temperature, the equivalent strain and the grain size. Since FE-simulation of open-die forging is very time consuming and requires a large numerical effort, the IBF developed fast calculation models for open-die forging, which allow the fast calculation of these decisive target values within seconds. Combined with a GUI, a property based design and optimization of open-die forging process can be successfully realized. Furthermore, these models offer a significant potential for teaching purposes as the correlations between forging parameters and resulting workpiece properties can be analyzed in a descriptive way.
For further information, please contact Martin Wolfgarten.
Image: Extended informations about the forging process using fast models, Copyright: IBF