In the design and production process of formed components the changes of important physical and technical properties of the material caused by the manufacturing process are already taken into account and these properties are specifically adjusted. This applies, for example, to the strength and residual stresses. Damage, i.e. in particular the process of formation and development of voids, is generally only considered with regard to component failure due to cracks. The paradigm shift propagated by the TRR 188 implying to consider damage already in the design and manufacturing process of formed components offers a great potential to realize components with higher performance (e.g. with regard to fatigue strength or relative stiffness in relation to the components’ mass). In order to achieve this goal and to make it usable e.g. for lightweight construction, an interdisciplinary consortium of scientists working on forming technology, materials science, and materials testing technology as well as mechanics cooperates within the TRR 188. New methods and technologies for controlling and predicting both damage and production-specific component properties are investigated and developed, taking into account metal-physical and rheological relationships.In the first funding period it was shown, based on simplified geometries and processes, that the healing of casting pores can be modeled quantitatively and can also be influenced by the process parameters. It was also possible to control damage in a cold forging process and to clearly prove the positive effects of reduced damage on the performance. The occurrence of new damage in sheet metal forming could be significantly reduced by novel forming methods. These technically usable results were only possible through the simultaneous development of new, efficient methods for damage characterization and new, regularized material models. In the second funding period complex component geometries and process sequences will be investigated in detail. The focus of modeling is on models that quantitatively predict the void surface area fraction and its influence on component performance, e.g. in terms of notched bar impact work and fatigue behavior. Furthermore, the interactions of damage mechanisms with microstructure evolution in hot working (e.g. via recrystallization) and their influence on the performance of hot formed components are investigated. Aims of the third funding period are the experimental and simulative investigation and optimization of the components’ performance along the entire process chain for complex forming processes. The implementation of the paradigm shift, outlined above, contributes to resource efficiency in many ways, e.g. by reducing safety factors through the optimal distribution of damage in formed components.

DFG Programme CRC/Transregios

• A02 - Influencing the evolution of damage in cold extrusion (Project Head Tekkaya, A. Erman )
• A04 - Evolution and healing of damage during the production of steel sheets by flat rolling (Project Heads Hirt, Gerhard ;  Münstermann, Sebastian )
• A05 - Damage in sheet metal bending of lightweight profiles (Project Head Tekkaya, A. Erman )
• A06 - Damage influence in deep drawing and stretch forming (Project Heads Bergs, Thomas ;  Klocke, Fritz ;  Mattfeld, Patrick )
• A07 - Damage controlled closed die forging via optimal geometry and process layout (Project Heads Bailly, David ;  Hirt, Gerhard )
• A08 - Thermo-mechanical treatment of microstructures for damage control in cold forming (Project Heads Hirt, Gerhard ;  Lohmar, Johannes ;  Münstermann, Sebastian ;  Springer, Hauke )
• B01 - Measurement-based characterization and prediction of ductile and cyclic damage interaction at the macroscale (Project Heads Menzel, Andreas ;  Walther, Frank )
• B02 - Mechanisms and statistics of deformation induced damage as a function of load path and microstructure (Project Heads Al-Samman, Talal ;  Korte-Kerzel, Ph.D., Sandra )
• B03 - Position resolved damage nucleation and growth at the microstructure length scale (Project Heads Dehm, Gerhard ;  Kirchlechner, Christoph ;  Ponge, Dirk )
• B04 - Multiscale electron microscope characterization of hardening and damage mechanisms (Project Heads Aretz, Anke ;  Schwedt, Alexander )
• B05 - Generic description of damage and microstructure for damage-tolerant material design (Project Head Münstermann, Sebastian )
• B06 - Combinatorial design of damage-tolerant dual-phase steel microstructures (Project Heads Sandlöbes-Haut, Stefanie ;  Springer, Hauke )
• C01 - Thermomechanically coupled damage model for operating loads – predicting service life of formed parts (Project Heads Kurzeja, Patrick ;  Mosler, Jörn ;  Walther, Frank )
• C02 - Macroscopic modeling of damage evolution in forming processes (Project Head Menzel, Andreas )
• C04 - Micromechanical modeling of damage in polycrystals based on enhanced crystal plasticity theory (Project Heads Klinge, Sandra ;  Mosler, Jörn )
• C05 - Sensitivity and optimization of damage in forming processes (Project Head Barthold, Franz-Joseph )
• S01 - Scientific service project – model integration for process simulation (Project Heads Clausmeyer, Till ;  Kaiser, Tobias ;  Ostwald, Richard )
• T01 - Damage evolution in the production of drive shafts by radial swaging and spline drawing (Project Head Tekkaya, A. Erman )
• T02 - Application of Artificial Intelligence inside the Scanning Electron Microscope for Accelerated High-Resolution in-situ Testing (Project Head Korte-Kerzel, Ph.D., Sandra )
• T03 - Investigation of damage development in hot metal forming process chains using the example of ring rolling (Project Heads Bailly, David ;  Hirt, Gerhard )
• Z - Central tasks of the collaborative research center (Project Heads Hirt, Gerhard ;  Tekkaya, A. Erman )

• A01 - Modeling and control of damage evolution in caliber hot rolling of steel rods (Project Head Hirt, Gerhard )
• C03 - Examination and modeling of the effect of measures influencing damage evolution during hot forming (Project Head Bambach, Markus )

Applicant Institution Rheinisch-Westfälische Technische Hochschule Aachen, since 1/2021

Co-Applicant Institution Technische Universität Dortmund

Participating University Karlsruher Institut für Technologie

Participating Institution Max-Planck-Institut für Nachhaltige Materialien GmbH (MPI SusMat)

Spokespersons Professor Dr.-Ing. Gerhard Hirt, from 1/2021 until 6/2023; Professor Dr.-Ing. A. Erman Tekkaya, since 7/2023