Abstract
Additive manufacturing (AM) is employed for fabricating industrial products with complex geometries. As topological optimization is suitable for designing complex geometries, studies have combined AM and topological optimization, evaluating the density optimization of lattice structures as a variant of topological optimization. The lattice structures of components fabricated via AM comprise voids. Models designed using topological optimization should be modified to ensure structures suitable for AM. As the lattice unit can be easily fabricated using AM with fewer design modifications, this study uses lattice density optimization for an industrial AM product. We propose a method of optimizing the lattice distribution for controlling the surface temperature uniformity of industrial products, such as molds. The effective thermal conductivity of the lattice is calculated using the homogenization and finite element methods. The effective thermal conductivity changes depending on the internal pore sizes. The proposed methodology is validated using a 3D example; the minimization problem of surface temperature variations in the target domain is considered. The variable density of the embedded lattice in the target domain is optimized, and we experimentally validated the performance of the lattice unit cell and optimal 3D structure using metal powder bed fusion AM.
Highlights
Controlling the temperature distribution within and on the surface of a product is essential in the molds and machinery used for production processes involving hightemperature environments; this is because the resulting thermal deformation can affect production quality
We address the steady-state thermal conduction problems of lattice unit cells composed of metallic materials with isotropic thermal conductivity as well as the Symmetry 2021, 13, 1194 density distribution optimization of unit cells in the design area, Ω
The lattice unit cell is structured as a cube with a cubic void
Summary
Controlling the temperature distribution within and on the surface of a product is essential in the molds and machinery used for production processes involving hightemperature environments; this is because the resulting thermal deformation can affect production quality. The high-efficiency cooling of molds and heat engine components and its application to heat exchangers are being studied actively [5]; this is because it is suitable for fabricating complex structures that contain internal voids. An advantage of such a mold is that it is possible to freely design the internal thermal conduction and cooling structure, considering that the temperature of the mold can be designed as intended, without introducing the active control technologies mentioned earlier
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