Project Details
Mechanical properties and hydrogen tolerance of particle-reinforced CCA produced by additive manufacturing (MarioCCArt)
Applicants
Professor Dr. Gerhard Dehm; Dr.-Ing. Nils Ellendt, since 7/2022; Professor Dr. Eric A. Jägle
Subject Area
Mechanical Properties of Metallic Materials and their Microstructural Origins
Materials in Sintering Processes and Generative Manufacturing Processes
Materials in Sintering Processes and Generative Manufacturing Processes
Term
from 2017 to 2021
Project identifier
Deutsche Forschungsgemeinschaft (DFG) - Project number 388738622
In the first funding period, the process chain for the synthesis of particle-reinforced HEA/CCA (High Entropy Alloys / Compositionally Complex Alloys) via gas atomization of powders and Laser Powder Bed Fusion (L-PBF) was established. We processed alloys in the family CoCrFeNi(-Al,-Mn) and investigated strengthening via spinodal decomposition, oxide and nitride precipitation. Continuing with this work, we will concentrate in the follow-up project on the most successful of these alloys (no crack formation in L-PBF, single-phase matrix) for more application-driven research. Two alloys will be investigated, both single-phase A1 (fcc), one HEA and one conventional alloy for reference. These alloys will be reinforced by particles of various chemical composition and size. The impact of these different particle sizes and compositions on processability in different ex-situ and in-situ process routes in L-PBF will be determined and the mechanical properties of the resulting particle-reinforced CCA (p-CCA) will be determined, including strength, fracture toughness and fatigue strength. Additionally, the influence of hydrogen and of low temperatures on the mechanical properties and on the microstructure will be a focus of the project. The goal of these analyses is to develop a strong, tough, fatigue- and hydrogen-resistant material. To this end, the mechanical properties and the mechanisms of plastic deformation of the p-CCA and reference alloys before and after gaseous hydrogen charging will be investigated at room temperature and at low temperatures. To understand the impact of hydrogen on plastic deformation and failure mechanisms, additionally a nanoindenter including an electrochemical charging cell will be used. The results lay the foundation of the application of p-CCA in the hydrogen economy.
DFG Programme
Priority Programmes
Ehemaliger Antragsteller
Dr.-Ing. Volker Uhlenwinkel, until 7/2022