Voxel and stereolithographic digital design framework in additive manufacturing: effects in a PolyJet printing process and relevant digital solutions

PolyJet printing in Additive Manufacturing (AM) allows creating multi-material distributions and complex hierarchical structures. AM typically uses tessellated Stereolithography (STL) files as digital data to define geometric and associated materials; it may not always be suitable as a digital model for multi-material structures. Voxel printing is a recent technique for multi-material structures that allows software processing of digital STL; it precludes a need to define each material region as a unique geometric entity. The present paper compares voxel 3D printing and directly used STL printing digital design framework in PolyJet printing. A selected geometric configuration was printed using voxel and STL digital designs. The effect on the final printed part's quality and fidelity from these digital designs is compared. The variations in the voxel-based printed part's dimensions resulted from the printer's resolution differences in two planar directions. Voxel printing also had incorrect material depositions in multi-material parts due to rasterization errors. Corrective digital software solutions for dimensional and rasterization errors were developed for voxel designs and are found to be effective. Process–Property effects from voxel and STL digital designs based on a two-material composite system's tensile mechanical properties are studied. Present work provides digital solutions as an effective means to mitigate any limitations in voxel-based digital designs for additive manufacturing of multi-material complex structures. AM's success and quality depend on digital designs, a careful understanding of induced digital approximation effects, and effective cyber-based solutions.

[1]  Nicholas Alexander Meisel,et al.  Design for Additive Manufacturing Considerations for Self-Actuating Compliant Mechanisms Created via Multi-Material PolyJet 3D Printing , 2015 .

[2]  Craig M. Hamel,et al.  3D printed two-dimensional periodic structures with tailored in-plane dynamic responses and fracture behaviors , 2018 .

[3]  Alin Stăncioiu,et al.  FROM CAD MODEL TO 3D PRINT VIA “STL” FILE FORMAT , 2010 .

[4]  Dorcas V. Kaweesa,et al.  Quantifying fatigue property changes in material jetted parts due to functionally graded material interface design , 2018 .

[5]  Andrea Ehrmann,et al.  Combining 3D printed forms with textile structures - mechanical and geometrical properties of multi-material systems , 2015 .

[6]  Tong Mei,et al.  Development of a new rapid prototyping interface , 1999 .

[7]  Ramesh Raskar,et al.  Active Printed Materials for Complex Self-Evolving Deformations , 2014, Scientific Reports.

[8]  Christopher B. Williams,et al.  Fatigue Characterization of 3D Printed Elastomer Material , 2012 .

[9]  J. Plocher,et al.  Review on design and structural optimisation in additive manufacturing: Towards next-generation lightweight structures , 2019 .

[10]  A. K. BREGT,et al.  Determination of rasterizing error a case study with the soil map of The Netherlands , 1991, Int. J. Geogr. Inf. Sci..

[11]  Dong Wang,et al.  A phase evolution based constitutive model for shape memory polymer and its application in 4D printing , 2020, Smart Materials and Structures.

[12]  Conner K. Dunn,et al.  Thermomechanically Triggered Two‐Stage Pattern Switching of 2D Lattices for Adaptive Structures , 2018 .

[13]  Neri Oxman,et al.  Voxel-based fabrication through material property mapping: A design method for bitmap printing , 2015, Comput. Aided Des..

[14]  Inigo F. Ituarte,et al.  Design and additive manufacture of functionally graded structures based on digital materials , 2019 .

[15]  Thomas S. Lumpe,et al.  Tensile properties of multi-material interfaces in 3D printed parts , 2019, Materials & Design.

[16]  OxmanNeri,et al.  Grown, Printed, and Biologically Augmented: An Additively Manufactured Microfluidic Wearable, Functionally Templated for Synthetic Microbes , 2016 .

[17]  Julien M. Claes,et al.  Iso-luminance counterillumination drove bioluminescent shark radiation , 2014, Scientific Reports.

[18]  Hod Lipson,et al.  Design and analysis of digital materials for physical 3D voxel printing , 2009 .

[19]  Shuaishuai Zhang,et al.  Interfacial strength-controlled energy dissipation mechanism and optimization in impact-resistant nacreous structure , 2019, Materials & Design.

[20]  Ole Sigmund,et al.  A 99 line topology optimization code written in Matlab , 2001 .

[21]  Ahmed Hosny,et al.  Making data matter: Voxel printing for the digital fabrication of data across scales and domains , 2018, Science Advances.

[22]  Processing and mechanical behavior of rigid and flexible material composite systems formed via voxel digital design in polyjet additive manufacturing , 2021 .

[23]  André R Studart,et al.  Additive manufacturing of biologically-inspired materials. , 2016, Chemical Society reviews.

[24]  Bashir Khoda,et al.  Hierarchical Scanning Data Structure for Additive Manufacturing , 2017 .

[25]  Characterization of mutli-material interfaces in polyjet additive manufacturing , 2020 .

[26]  Lars Pejryd,et al.  3D Data Export for Additive Manufacturing - Improving Geometric Accuracy , 2016 .

[27]  Martin L. Dunn,et al.  Active origami by 4D printing , 2014 .