Adaptive Variable Design Algorithm for Improving Topology Optimization in Additive Manufacturing Guided Design

CAD-CAE software companies have introduced numerous tools aimed at facilitating topology optimization through Finite Element Simulation, thereby enhancing accessibility for designers via user-friendly interfaces. However, the imposition of intricate constraint conditions or additional restrictions d...

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Bibliographic Details
Published inInventions (Basel) Vol. 9; no. 4; p. 70
Main Authors Vadillo Morillas, Abraham, Meneses Alonso, Jesús, Bustos Caballero, Alejandro, Castejón Sisamón, Cristina, Ceruti, Alessandro
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.07.2024
Subjects
3-D printers
Adaptive algorithms
Additive manufacturing
Algorithms
Automobile racing
Case studies
Codes
Compliance
Design for manufacturability
Design optimization
Design parameters
Designers
discreteness
Interface stability
Manufacturability
Matlab
optimization software
performance optimization
Simulation
Software packages
Software upgrading
Topology optimization
Variables
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Summary:CAD-CAE software companies have introduced numerous tools aimed at facilitating topology optimization through Finite Element Simulation, thereby enhancing accessibility for designers via user-friendly interfaces. However, the imposition of intricate constraint conditions or additional restrictions during calculations may introduce instability into the resultant outcomes. In this paper, an algorithm for updating the design variables called Adaptive Variable Design is proposed to keep the final design space volume of the optimized part consistently under the target value while giving the main algorithm multiple chances to update the optimization parameters and search for a valid design. This algorithm aims to produce results that are more conducive to manufacturability and potentially more straightforward in interpretation. A comparison between several commercial software packages and the proposed algorithm, implemented in MATLAB R2023a, is carried out to prove the robustness of the latter. By simulating identical parts under similar conditions, we seek to generate comparable results and underscore the advantages stemming from the adoption and comprehension of the proposed topology optimization methodology. Our findings reveal that the integrated enhancements within MATLAB pertaining to the topology optimization process yield favourable outcomes with respect to discretization and the manufacturability of the resultant geometries. Furthermore, we assert that the methodology evaluated within MATLAB holds promise for potential integration into commercial packages, thereby enhancing the efficiency of topology optimization processes.
ISSN:2411-5134
2411-5134
DOI:10.3390/inventions9040070