TY - GEN

T1 - Multiphysical simulation approach for specifying material properties of additively manufactured laser heat sinks

T2 - Potentials and challenges

AU - Röttger, Julian

AU - Grabe, Tobias

AU - Biermann, Tobias

AU - Ziebehl, Arved

AU - Ley, Peer-Phillip

AU - Wolf, Alexander Gordon

AU - Lachmayer, Roland Johann

PY - 2021/11/17

Y1 - 2021/11/17

N2 - Additive manufacturing of laser heat sinks enables the optimization of cooling channel geometries and the integration of various functions within a single component. Lightweight and cost-effective designs can be realized using the fused filament fabrication process. Due to this manufacturing process, only a limited selection of materials is available. An appropriate choice of filament is crucial, since the material properties have a direct influence on the resulting thermal and mechanical stress in the laser crystal. A multiphysical simulation model in combination with a parametric material model is set up to investigate the influence of the properties of the heat sink on the resulting thermal loads in the crystal.

AB - Additive manufacturing of laser heat sinks enables the optimization of cooling channel geometries and the integration of various functions within a single component. Lightweight and cost-effective designs can be realized using the fused filament fabrication process. Due to this manufacturing process, only a limited selection of materials is available. An appropriate choice of filament is crucial, since the material properties have a direct influence on the resulting thermal and mechanical stress in the laser crystal. A multiphysical simulation model in combination with a parametric material model is set up to investigate the influence of the properties of the heat sink on the resulting thermal loads in the crystal.

UR - https://www.dgao-proceedings.de/download/122/122_a13.pdf

U2 - 10.15488/11521

DO - 10.15488/11521

M3 - Conference contribution

BT - DGaO-Proceedings 2021

ER -