The great flexibility provided by generative manufacturing offers immense potential for the structural component optimization. However, this freedom needs to be utilized by appropriate CAx tools. In this paper, we present a novel slicing method, enabling the automatic generation of topology-optimized Laminated Layer Manufacturing (LLM) parts. With this method a part of arbitrary shape can be automatically sliced and equipped with a uniform virtual grid that is suitable for manufacturing. The optimal density distribution is then mapped onto the individual slices and locally approximated through the introduction of variably shaped cavities. By using 3D modeling techniques all LLM sheets are modeled parametrically and assembled automatically. To verify the functionality of the presented method, it is applied to two practical parts and compared with a conventional topology optimization method.
%0 Journal Article
%1 Helfesrieder.2020
%A Helfesrieder, Nico
%A Lechler, Armin
%A Verl, Alexander
%D 2020
%J Procedia CIRP
%K generative imported isw manufacturing myown optimization xhr
%P 38--43
%R 10.1016/j.procir.2020.04.048
%T Method for generating manufacturable, topology-optimized parts for Laminated Layer Manufacturing
%U http://www.sciencedirect.com/science/article/pii/S2212827120306144
%V 93
%X The great flexibility provided by generative manufacturing offers immense potential for the structural component optimization. However, this freedom needs to be utilized by appropriate CAx tools. In this paper, we present a novel slicing method, enabling the automatic generation of topology-optimized Laminated Layer Manufacturing (LLM) parts. With this method a part of arbitrary shape can be automatically sliced and equipped with a uniform virtual grid that is suitable for manufacturing. The optimal density distribution is then mapped onto the individual slices and locally approximated through the introduction of variably shaped cavities. By using 3D modeling techniques all LLM sheets are modeled parametrically and assembled automatically. To verify the functionality of the presented method, it is applied to two practical parts and compared with a conventional topology optimization method.
@article{Helfesrieder.2020,
abstract = {The great flexibility provided by generative manufacturing offers immense potential for the structural component optimization. However, this freedom needs to be utilized by appropriate CAx tools. In this paper, we present a novel slicing method, enabling the automatic generation of topology-optimized Laminated Layer Manufacturing (LLM) parts. With this method a part of arbitrary shape can be automatically sliced and equipped with a uniform virtual grid that is suitable for manufacturing. The optimal density distribution is then mapped onto the individual slices and locally approximated through the introduction of variably shaped cavities. By using 3D modeling techniques all LLM sheets are modeled parametrically and assembled automatically. To verify the functionality of the presented method, it is applied to two practical parts and compared with a conventional topology optimization method.},
added-at = {2020-09-23T09:31:28.000+0200},
author = {Helfesrieder, Nico and Lechler, Armin and Verl, Alexander},
biburl = {https://puma.ub.uni-stuttgart.de/bibtex/243ebdfc4a55530b8318de4ec1df7ea95/isw-bibliothek},
doi = {10.1016/j.procir.2020.04.048},
interhash = {98098ca9e57475ca9a589581cc7237e0},
intrahash = {43ebdfc4a55530b8318de4ec1df7ea95},
issn = {22128271},
journal = {Procedia CIRP},
keywords = {generative imported isw manufacturing myown optimization xhr},
pages = {38--43},
timestamp = {2020-09-23T07:35:19.000+0200},
title = {Method for generating manufacturable, topology-optimized parts for Laminated Layer Manufacturing},
url = {http://www.sciencedirect.com/science/article/pii/S2212827120306144},
volume = 93,
year = 2020
}
