Your search keyword '"Weihe, Stefan"' showing total 5 results

1. Micro-Twinning in IN738LC Manufactured with Laser Powder Bed Fusion

Author

Megahed, Sandra, Krämer, Karl Michael, Kontermann, Christian, Heinze, Christoph, Udoh, Annett, Weihe, Stefan, Oechsner, Matthias, Megahed, Sandra, Krämer, Karl Michael, Kontermann, Christian, Heinze, Christoph, Udoh, Annett, Weihe, Stefan, and Oechsner, Matthias

Abstract

Components manufactured with Metal Laser Powder Bed Fusion (PBF-LB/M) are built in a layerwise fashion. The PBF-LB/M build orientation affects grain morphology and orientation. Depending on the build orientation, microstructures from equiaxed to textured grains can develop. In the case of a textured microstructure, a clear anisotropy of the mechanical properties affecting short- and long-term mechanical properties can be observed, which must be considered in the component design. Within the scope of this study, the IN738LC tensile and creep properties of PBF-LB/M samples manufactured in 0° (perpendicular to build direction), 45° and 90° (parallel to build direction) build orientations were investigated. While the hot tensile results (at 850 °C) are as expected, where the tensile properties of the 45° build orientation lay between those of 0° and 90°, the creep results (performed at 850 °C and 200 MPa) of the 45° build orientation show the least time to rupture. This study discusses the microstructural reasoning behind the peculiar creep behavior of 45° oriented IN738LC samples and correlates the results to heat-treated microstructures and the solidification conditions of the PBF-LB/M process itself.

Published

2023

2. Micro-Twinning in IN738LC Manufactured with Laser Powder Bed Fusion

Author

Megahed, Sandra, Krämer, Karl Michael, Kontermann, Christian, Heinze, Christoph, Udoh, Annett, Weihe, Stefan, Oechsner, Matthias, Megahed, Sandra, Krämer, Karl Michael, Kontermann, Christian, Heinze, Christoph, Udoh, Annett, Weihe, Stefan, and Oechsner, Matthias

Abstract

Components manufactured with Metal Laser Powder Bed Fusion (PBF-LB/M) are built in a layerwise fashion. The PBF-LB/M build orientation affects grain morphology and orientation. Depending on the build orientation, microstructures from equiaxed to textured grains can develop. In the case of a textured microstructure, a clear anisotropy of the mechanical properties affecting short- and long-term mechanical properties can be observed, which must be considered in the component design. Within the scope of this study, the IN738LC tensile and creep properties of PBF-LB/M samples manufactured in 0° (perpendicular to build direction), 45° and 90° (parallel to build direction) build orientations were investigated. While the hot tensile results (at 850 °C) are as expected, where the tensile properties of the 45° build orientation lay between those of 0° and 90°, the creep results (performed at 850 °C and 200 MPa) of the 45° build orientation show the least time to rupture. This study discusses the microstructural reasoning behind the peculiar creep behavior of 45° oriented IN738LC samples and correlates the results to heat-treated microstructures and the solidification conditions of the PBF-LB/M process itself.

Published

2023

3. Micro-Twinning in IN738LC Manufactured with Laser Powder Bed Fusion

Author

Megahed, Sandra, Krämer, Karl Michael, Kontermann, Christian, Heinze, Christoph, Udoh, Annett, Weihe, Stefan, Oechsner, Matthias, Megahed, Sandra, Krämer, Karl Michael, Kontermann, Christian, Heinze, Christoph, Udoh, Annett, Weihe, Stefan, and Oechsner, Matthias

Abstract

Components manufactured with Metal Laser Powder Bed Fusion (PBF-LB/M) are built in a layerwise fashion. The PBF-LB/M build orientation affects grain morphology and orientation. Depending on the build orientation, microstructures from equiaxed to textured grains can develop. In the case of a textured microstructure, a clear anisotropy of the mechanical properties affecting short- and long-term mechanical properties can be observed, which must be considered in the component design. Within the scope of this study, the IN738LC tensile and creep properties of PBF-LB/M samples manufactured in 0° (perpendicular to build direction), 45° and 90° (parallel to build direction) build orientations were investigated. While the hot tensile results (at 850 °C) are as expected, where the tensile properties of the 45° build orientation lay between those of 0° and 90°, the creep results (performed at 850 °C and 200 MPa) of the 45° build orientation show the least time to rupture. This study discusses the microstructural reasoning behind the peculiar creep behavior of 45° oriented IN738LC samples and correlates the results to heat-treated microstructures and the solidification conditions of the PBF-LB/M process itself.

Published

2023

4. Micro-Twinning in IN738LC Manufactured with Laser Powder Bed Fusion

Author

Megahed, Sandra, Krämer, Karl Michael, Kontermann, Christian, Heinze, Christoph, Udoh, Annett, Weihe, Stefan, Oechsner, Matthias, Megahed, Sandra, Krämer, Karl Michael, Kontermann, Christian, Heinze, Christoph, Udoh, Annett, Weihe, Stefan, and Oechsner, Matthias

Abstract

Components manufactured with Metal Laser Powder Bed Fusion (PBF-LB/M) are built in a layerwise fashion. The PBF-LB/M build orientation affects grain morphology and orientation. Depending on the build orientation, microstructures from equiaxed to textured grains can develop. In the case of a textured microstructure, a clear anisotropy of the mechanical properties affecting short- and long-term mechanical properties can be observed, which must be considered in the component design. Within the scope of this study, the IN738LC tensile and creep properties of PBF-LB/M samples manufactured in 0° (perpendicular to build direction), 45° and 90° (parallel to build direction) build orientations were investigated. While the hot tensile results (at 850 °C) are as expected, where the tensile properties of the 45° build orientation lay between those of 0° and 90°, the creep results (performed at 850 °C and 200 MPa) of the 45° build orientation show the least time to rupture. This study discusses the microstructural reasoning behind the peculiar creep behavior of 45° oriented IN738LC samples and correlates the results to heat-treated microstructures and the solidification conditions of the PBF-LB/M process itself.

Published

2023

5. Micromechanical fatigue experiments for validation of microstructure-sensitive fatigue simulation models

Author

Durmaz, Ali Riza, Natkowski, Erik, Arnaudov, Nikolai, Sonnweber-Ribic, Petra, Weihe, Stefan, Münstermann, Sebastian, Eberl, Chris, Gumbsch, Peter, Durmaz, Ali Riza, Natkowski, Erik, Arnaudov, Nikolai, Sonnweber-Ribic, Petra, Weihe, Stefan, Münstermann, Sebastian, Eberl, Chris, and Gumbsch, Peter

Abstract

Crack initiation governs high cycle fatigue life and is susceptible to microstructural details. While corresponding microstructure-sensitive models are available, their validation is difficult. We propose a validation framework where a fatigue test is mimicked in a sub-modeling simulation by embedding the measured microstructure into the specimen geometry and adopting the experimental boundary conditions. Exemplary, a phenomenological crystal plasticity model was applied to predict deformation in ferritic steel (EN1.4003). Hotspots in commonly used fatigue indicator parameter maps are compared with damage segmented from micrographs. Along with the data, the framework is published for benchmarking future micromechanical fatigue models.

Published

2021