%0 Conference Paper %1 Michel_2024 %A Michel, Johannes %A Ulff, Nico %A Henn, Manuel %A Simonds, Brian %A Hosemann, Peter %A Zanger, Frederik %A Hagenlocher, Christian %A Graf, Thomas %B Laser 3D Manufacturing XI %D 2024 %E Gu, Bo %E Chen, Hongqiang %I SPIE %K %R 10.1117/12.3002302 %T Adjusting the microstructure of additively manufactured parts with tailored temperature fields by the combination of powder bed fusion with cw-laser and ablation with ultrashort laser pulses %U http://dx.doi.org/10.1117/12.3002302 %V 12876 %X In powder bed fusion with laser beams (PBF-LB/M), the component's quality and mechanical properties are limited by restricted process parameter combinations and the geometry of the component. Combining PBF-LB/M with ultrashort laser ablation enables additional control of the heat flow to adjust local solidification. On the one hand it is possible to print heat-dissipating structures, which can be added and removed during the build process. On the other hand, ablated slits in the component can serve as a thermal barrier. To investigate the effect of slits and heat-dissipation structures on the local temperature field and solidification conditions, a numerical model was developed. Two different ablation strategies were investigated and compared to conventional PBF-LB. Numerical investigations of an additively manufactured AlSi10Mg component showed a larger melt pool, a lower temperature gradient, and a lower cooling rate if there are slits present next to the current PBF-LB track. This approach provides the potential to independently adjust microstructure and mechanical properties, exceeding limitations imposed by the component's geometry in conventional additive manufacturing.

@inproceedings{Michel_2024, abstract = {In powder bed fusion with laser beams (PBF-LB/M), the component's quality and mechanical properties are limited by restricted process parameter combinations and the geometry of the component. Combining PBF-LB/M with ultrashort laser ablation enables additional control of the heat flow to adjust local solidification. On the one hand it is possible to print heat-dissipating structures, which can be added and removed during the build process. On the other hand, ablated slits in the component can serve as a thermal barrier. To investigate the effect of slits and heat-dissipation structures on the local temperature field and solidification conditions, a numerical model was developed. Two different ablation strategies were investigated and compared to conventional PBF-LB. Numerical investigations of an additively manufactured AlSi10Mg component showed a larger melt pool, a lower temperature gradient, and a lower cooling rate if there are slits present next to the current PBF-LB track. This approach provides the potential to independently adjust microstructure and mechanical properties, exceeding limitations imposed by the component's geometry in conventional additive manufacturing.}, added-at = {2024-05-08T20:35:51.000+0200}, author = {Michel, Johannes and Ulff, Nico and Henn, Manuel and Simonds, Brian and Hosemann, Peter and Zanger, Frederik and Hagenlocher, Christian and Graf, Thomas}, biburl = {https://puma.ub.uni-stuttgart.de/bibtex/2c47506f57bff71e5a4b18dd91640762f/jmichel}, booktitle = {Laser 3D Manufacturing XI}, doi = {10.1117/12.3002302}, editor = {Gu, Bo and Chen, Hongqiang}, eventdate = {27 January - 1 February 2024}, eventtitle = {LASE Photonics West}, interhash = {65b5dae017fa6d9aac205df60afb2244}, intrahash = {c47506f57bff71e5a4b18dd91640762f}, keywords = {}, language = {english}, month = mar, publisher = {SPIE}, series = {Proc. SPIE}, timestamp = {2024-05-08T18:35:51.000+0200}, title = {Adjusting the microstructure of additively manufactured parts with tailored temperature fields by the combination of powder bed fusion with cw-laser and ablation with ultrashort laser pulses}, url = {http://dx.doi.org/10.1117/12.3002302}, venue = {San Francisco, California, United States}, volume = 12876, year = 2024 }