Schottstedt, L.Scholze, M.Wagner, M. F.-X.2025-09-162025-09-162025-08-26http://hdl.handle.net/2003/4393110.17877/DE290R-25699Adiabatic Shear Band formation is observed in high-speed shear deformation of metallic materials, particularly in technologically relevant processes. It is characterized by the formation of increasingly localized areas of high shear strains. Depending on the selected process parameters, high-speed or adiabatic blanking can lead to the formation of an adiabatic shear band in the newly generated surface. These blanked surfaces have outstanding properties (e.g. high hardness, low rollover, low roughness, almost no burr) and can be used directly as functional surfaces. This reduces the need for complex and expensive, additional mechanical surface processing, significantly shortening the process chain and thus saving energy. In this contribution, we investigate the thermo-mechanical behavior and shear band formation of a press-hardened martensitic steel 22MnB5 under different strain rates. Tensile and compression tests are performed at different temperatures (in the range from 293 to 673 K) and in a wide range of nominal strain rates between 10-3 and 4∙10 3 s-1. In addition, we use S-shaped samples to introduce a simple shear stress state to generate (adiabatic) shear bands, again while applying quasi-static and dynamic (nominal) strain rates, respectively. The plane surface of this sample geometry enables an in-situ observation of local strain fields by digital image correlation. We show the mechanical similarities and differences of dynamic versus quasi-static shear experiments using digital image correlation. Our experimental approach contributes to a deeper understanding of the rate and stress-state dependent formation of shear bands in press-hardened steels.enthermo-mechanical behaviordynamic testingstrain rate dependencyshear band620670ConferencePaperScherbandThermomechanische EigenschaftSpannungs-Dehnungs-BeziehungMangan-Bor-StahlFormhärtenZerstörungsfreie WerkstoffprüfungBildkorrelation