Adaptive Concurrent Topology Optimization of Coated Structures with Nonperiodic Infill for Additive Manufacturing

The present research develops a direct multiscale topology optimization method for additive manufacturing (AM) of coated structures with nonperiodic infill by employing an adaptive mapping technique of adaptive geometric components (AGCs). The AGCs consist of a framework of macro-sandwich bars that...

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Bibliographic Details
Published in:Computer aided design 2020-12, Vol.129, p.102918, Article 102918
Main Authors: Hoang, Van-Nam, Tran, Phuong, Nguyen, Ngoc-Linh, Hackl, Klaus, Nguyen-Xuan, H.
Format: Article
Language:English
Subjects:
Adaptive geometric components
Additive manufacturing
Cellular structure
Coated structure
Coating
Direct multiscale topology optimization
Finite element method
Iterative methods
Macrostructure
Mapping
Microstructure
Multiscale optimization
Optimization
Porosity
Redevelopment
Shell-infill design
Three dimensional printing
Topology optimization
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Summary:The present research develops a direct multiscale topology optimization method for additive manufacturing (AM) of coated structures with nonperiodic infill by employing an adaptive mapping technique of adaptive geometric components (AGCs). The AGCs consist of a framework of macro-sandwich bars that represent the macrostructure with the solid coating and a network of micro-solid bars that represent the nonperiodic infill at the microstructural scale. The macrostructure including the coating skin and the internal architecture of the microstructures of cellular structures is simultaneously optimized by straightforwardly searching optimal geometries of the AGCs. Compared with most existing methods, the proposed method does not require material homogenization technique at the microscale; the continuity of microstructures and structural porosities are ensured without additional constraints; Finite element analysis (FEA) and geometric parameter updates are required only once for each optimization iteration. AGCs allow us to model coated structures with porosity infill on a coarse finite element mesh. The adaptive mapping technique may reduce mapping time by up to 50%. Besides, it is easy to control the length scales of the coating and infill as desired to make it possible with AM. This investigation also explores the ability to realize concurrent designs of coated structures with nonperiodic infill patterns using 3D printing techniques. •Explicit topology optimization of coated structures with nonperiodic infill is proposed.•The structure, including the macrostructural topology, coating and infill, is simultaneously optimized without material homogenization and connector and local volume constraints.•Structural feature sizes are explicitly controlled without filtering techniques or additional constraints.•The coated structure with porous infill can be simply designed in a coarse finite element grid.•Concurrent designs of coated structures with nonperiodic infill are then realized by using 3D printing techniques.
ISSN:0010-4485
1879-2685
DOI:10.1016/j.cad.2020.102918