Abstract: Systems and methods are disclosed that overcome problems with conventional filters for high temperature casting materials. According to embodiments, uniform, engineered filters enable consistent and repeatable metal flow rates without becoming a secondary source of contamination. Proven Additive Manufacturing (AM) methods generate engineered filters that achieve consistent filtration efficiency and predictable metal flow into a casting mold. Through this application of AM for ceramics, the resulting filter incorporates features that can be adjusted on-demand to address the needs of specific alloys and geometries applied in the production of castings. According to an embodiment, the method includes generating, using an additive manufacturing apparatus, a plurality of layers, wherein each layer includes individual ceramic ligaments arranged in a grid pattern having a two-dimensional rotational orientation. The method further includes stacking the layers along a thickness direction to form the filter.

Abstract: A disclosed system includes an additive manufacturing printer that performs a layer by layer three-dimensional printing process generating a casting mold based on a three-dimensional numerical specification. The numerical specification is based on a desired casting shape, including internal features such as hollow areas formed by cores, and is further based on a thermo-mechanical model of a casting process. The numerical specification describes variations in material and geometric properties of one or more layers of the casting mold corresponding to variations in the thermal and mechanical properties of the casting processes, as predicted by the thermo-mechanical model. The system may vary the thickness of features of the casting mold, based on predicted cooling rates, to reduce cooling non-uniformities and to provide for controlled, predictable cooling of the casting. The system may further generate trusses and heat sinks in the mold to respectively strengthen and weaken various features of the mold.