Virtual Material Design in 3D Printing Makes Headway with Multiscale Modeling

Marco Barink, Erica Coenen, TNO, Netherlands

The advantages of anisotropic properties in 3D printing materials have been difficult to exploit for product design, limited by material manufacturing and production methods. However, additive manufacturing is opening doors to material fabrication, allowing engineers to virtually design varying material properties into a single product. At the Netherlands Organization for Applied Scientific Research (TNO), researchers investigated virtual material design using multiphysics simulation and multiscale modeling.

To develop a procedure for designing anisotropy into 3D-printed structures, the researchers used COMSOL Multiphysics to study mechanical behavior in a unit cell, control material properties and the orientation of anisotropic fibers, and optimize local material distribution to achieve desired overall properties. To study material design on a larger scale, they extracted material parameters from the unit cell to include in a model of a full-scale 3D-printed object, and successfully applied methods of fully-coupled multiscale modeling to geometry and material design in several different applications.

COMSOL simulation results using the multiscale modeling procedure developed at TNO. The bottom model shows the multi-scale model with homogenized material properties from the microscale model shown on top.

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