Litcius/Paper detail

Design and additive manufacturing of novel conformal cooling molds

Chaolin Tan, Di Wang, Wenyou Ma, Yaorong Chen, Shijin Chen, Yongqiang Yang, Kesong Zhou

2020Materials & Design120 citationsDOIOpen Access PDF

Abstract

Additive manufacturing (AM) offers high-freedom in the design and processing of components with complex internal structures. In this work, a new injection mold with the self-supporting large cooling channel and tailored porous structures was designed to improve cooling efficiency and save AM build costs. The optimized internal supports suppressed the collapse and warpage of large channels, which improves the manufacturability and breaks the geometric constraints of laser powder bed fusion (LPBF). The formable diameter of self-supporting channels is significantly increased (≥20 mm). In comparison to the 8 mm normal-sized channel, the self-supporting 13 mm channel reduces the cooling time of more than 20%. Additionally, the porous diamond structure was designated in the assembly part of the mold to save the materials and build time. To tune the strength, a core-shell composite structure with solid shell surrounding inner porous structures is designed. The influence of the wall thickness on the mechanical property of the composite structure was explored, which guides the specific mold design. Finally, a mold with the above-mentioned novel design was successfully processed by LPBF, which substantiates the manufacturability of innovative design. This work also inspires other industrial applications of AM-processed components with improved performance and functionality.

Topics & Concepts

Design for manufacturabilityMaterials scienceMoldPorosityShell (structure)Composite numberChannel (broadcasting)Mechanical engineeringCore (optical fiber)Conformal mapFusionComposite materialComputer scienceEngineeringComputer networkMathematicsPhilosophyMathematical analysisLinguisticsAdditive Manufacturing and 3D Printing TechnologiesInjection Molding Process and PropertiesAdditive Manufacturing Materials and Processes