Design of variable thickness triply periodic surfaces for additive manufacturing

Minimal surfaces are receiving a renewed interest in biomedical and industrial fields, due to the capabilities of additive manufacturing technologies which allow very complex shapes. In this paper, an approach for geometric modeling of variable thickness triply periodic minimal surfaces in a CAD environment is proposed. The approach consists of three main steps: the definition of an initial mesh, the adoption of a subdivision scheme and the assignment of a variable thickness by a differential offset. Moreover, the relationship between relative density and mesh thickness was established for two types of minimal surfaces: Schoen’s gyroid, Schwarz’ Primitive. The proposed method improves the main issues highlighted in literature in the modeling of cellular materials and allows to easily obtain a consistent polygonal mesh model satisfying functional requirements. Two test cases were presented: the first shows a gradient thickness gyroid; in the second the relative density obtained by topology optimization was adopted in our modeling approach using a Schwarz’ Primitive. In both cases, guidelines for selecting the geometric modeling parameters taking into account the specific additive manufacturing process constraints were discussed. The proposed method opens new perspectives in the development of effective CAD tools for additive manufacturing, improving the shape complexity and data exchange capacity in cellular solid modeling.

[1]  Massimiliano Fantini,et al.  TPMS for interactive modelling of trabecular scaffolds for Bone Tissue Engineering , 2017 .

[2]  Yanling Tian,et al.  Novel real function based method to construct heterogeneous porous scaffolds and additive manufacturing for use in medical engineering. , 2015, Medical engineering & physics.

[3]  Liang Hao,et al.  Advanced lightweight 316L stainless steel cellular lattice structures fabricated via selective laser melting , 2014 .

[4]  Wen Feng Lu,et al.  Energy absorption characteristics of metallic triply periodic minimal surface sheet structures under compressive loading , 2018, Additive Manufacturing.

[5]  Albert C. To,et al.  Efficient Design-Optimization of Variable-Density Hexagonal Cellular Structure by Additive Manufacturing: Theory and Validation , 2015 .

[6]  Yi-Chung Hu,et al.  Optimization Theory, Methods, and Applications in Engineering 2014 , 2012 .

[7]  Jianzhong Fu,et al.  A review of the design methods of complex topology structures for 3D printing , 2018, Visual Computing for Industry, Biomedicine, and Art.

[8]  Rashid K. Abu Al-Rub,et al.  Nature‐Inspired Lightweight Cellular Co‐Continuous Composites with Architected Periodic Gyroidal Structures , 2018 .

[9]  Dirk Mohr,et al.  Mechanical performance of additively-manufactured anisotropic and isotropic smooth shell-lattice materials: Simulations & experiments , 2019, Journal of the Mechanics and Physics of Solids.

[10]  Jörg Peters,et al.  A realtime GPU subdivision kernel , 2005, SIGGRAPH 2005.

[11]  Nan Yang,et al.  Multi-morphology transition hybridization CAD design of minimal surface porous structures for use in tissue engineering , 2014, Comput. Aided Des..

[12]  C. Yan,et al.  Mechanical response of a triply periodic minimal surface cellular structures manufactured by selective laser melting , 2018, International Journal of Mechanical Sciences.

[13]  D. Yoo Porous scaffold design using the distance field and triply periodic minimal surface models. , 2011, Biomaterials.

[14]  H Weinans,et al.  Additively manufactured metallic porous biomaterials based on minimal surfaces: A unique combination of topological, mechanical, and mass transport properties. , 2017, Acta biomaterialia.

[15]  David Rosen,et al.  Design of truss-like cellular structures using relative density mapping method , 2015 .

[16]  Jiawei Feng,et al.  Porous scaffold design by solid T-splines and triply periodic minimal surfaces , 2018, Computer Methods in Applied Mechanics and Engineering.

[17]  Botao Zhang,et al.  Design of Variable-Density Structures for Additive Manufacturing Using Gyroid Lattices , 2017 .

[18]  A. Pourkamali Anaraki,et al.  Compressive characteristics of radially graded porosity scaffolds architectured with minimal surfaces. , 2018, Materials science & engineering. C, Materials for biological applications.

[19]  Dongjin Yoo,et al.  New paradigms in internal architecture design and freeform fabrication of tissue engineering porous scaffolds. , 2012, Medical engineering & physics.

[20]  R. Everson,et al.  Advanced lattice support structures for metal additive manufacturing , 2013 .

[21]  Vikram Deshpande,et al.  The stiffness and strength of the gyroid lattice , 2014 .

[22]  Liang Hao,et al.  Ti-6Al-4V triply periodic minimal surface structures for bone implants fabricated via selective laser melting. , 2015, Journal of the mechanical behavior of biomedical materials.

[23]  Monica Bordegoni,et al.  The Design Process of Additively Manufactured Mesoscale Lattice Structures: A Review , 2018, J. Comput. Inf. Sci. Eng..

[24]  Les A. Piegl,et al.  The NURBS Book , 1995, Monographs in Visual Communication.

[25]  A. Yánez,et al.  Compressive behaviour of gyroid lattice structures for human cancellous bone implant applications. , 2016, Materials science & engineering. C, Materials for biological applications.

[26]  Alexander A. Pasko,et al.  Procedural function-based modelling of volumetric microstructures , 2011, Graph. Model..

[27]  Chaoyang Wang,et al.  Minimal surface designs for porous materials: from microstructures to mechanical properties , 2018, Journal of Materials Science.

[28]  A. P. Anaraki,et al.  Additive manufacturing and mechanical characterization of graded porosity scaffolds designed based on triply periodic minimal surface architectures. , 2016, Journal of the mechanical behavior of biomedical materials.

[29]  K. Khan,et al.  Time dependent response of architectured Neovius foams , 2017 .

[30]  Ahmed S. Dalaq,et al.  Finite element prediction of effective elastic properties of interpenetrating phase composites with architectured 3D sheet reinforcements , 2016 .

[31]  Gianpaolo Savio,et al.  3D Model Representation and Data Exchange for Additive Manufacturing , 2019, Advances on Mechanics, Design Engineering and Manufacturing II.

[32]  Rashid K. Abu Al-Rub,et al.  Mechanical Properties of a New Type of Architected Interpenetrating Phase Composite Materials , 2017 .

[33]  Gianpaolo Savio,et al.  Geometric Modeling of Cellular Materials for Additive Manufacturing in Biomedical Field: A Review , 2018, Applied bionics and biomechanics.

[34]  H. Schwarz Gesammelte mathematische Abhandlungen , 1970 .

[35]  A. Schoen Infinite periodic minimal surfaces without self-intersections , 1970 .

[36]  Liang Hao,et al.  Microstructure and mechanical properties of aluminium alloy cellular lattice structures manufactured by direct metal laser sintering , 2015 .

[37]  J. Grotowski,et al.  High specific strength and stiffness structures produced using selective laser melting , 2014 .

[38]  S. Rosso,et al.  Implications of modeling approaches on the fatigue behavior of cellular solids , 2019, Additive Manufacturing.

[39]  Rashid K. Abu Al-Rub,et al.  The effect of architecture on the mechanical properties of cellular structures based on the IWP minimal surface , 2018 .

[40]  Gianpaolo Savio,et al.  Geometric modeling of lattice structures for additive manufacturing , 2018 .

[41]  David W. Rosen,et al.  Design for Additive Manufacturing , 2015, Additive Manufacturing Technologies.

[42]  E. Catmull,et al.  Recursively generated B-spline surfaces on arbitrary topological meshes , 1978 .

[43]  Liya Zhu,et al.  A TPMS-based method for modeling porous scaffolds for bionic bone tissue engineering , 2018, Scientific Reports.

[44]  Jaemin Shin,et al.  Finite Element Analysis of Schwarz P Surface Pore Geometries for Tissue-Engineered Scaffolds , 2012 .

[45]  Matthias Wessling,et al.  Estimation of the structure dependent performance of 3-D rapid prototyped membranes , 2015 .

[46]  Amir A Zadpoor,et al.  Bone tissue regeneration: the role of scaffold geometry. , 2015, Biomaterials science.

[47]  Adedeji Aremu,et al.  A voxel-based method of constructing and skinning conformal and functionally graded lattice structures suitable for additive manufacturing , 2017 .

[48]  J. Kruth,et al.  Fatigue behaviour of NiTi shape memory alloy scaffolds produced by SLM, a unit cell design comparison. , 2017, Journal of the mechanical behavior of biomedical materials.

[49]  Yaoyao Fiona Zhao,et al.  Bidirectional Evolutionary Structural Optimization (BESO) based design method for lattice structure to be fabricated by additive manufacturing , 2015, Comput. Aided Des..

[50]  Klaus Mecke,et al.  Minimal surface scaffold designs for tissue engineering. , 2011, Biomaterials.

[51]  Michael E. Mortenson,et al.  Geometric Modeling , 2008, Encyclopedia of GIS.

[52]  Ahmed Hussein,et al.  Evaluations of cellular lattice structures manufactured using selective laser melting , 2012 .

[53]  R. Ambu,et al.  Design and analysis of tissue engineering scaffolds based on open porous non-stochastic cells , 2017 .

[54]  Rashid K. Abu Al-Rub,et al.  Topology-mechanical property relationship of 3D printed strut, skeletal, and sheet based periodic metallic cellular materials , 2018 .

[55]  Christopher B. Williams,et al.  Insights into the mechanical properties of several triply periodic minimal surface lattice structures made by polymer additive manufacturing , 2017, Polymer.

[56]  Dong-Jin Yoo,et al.  An advanced multi-morphology porous scaffold design method using volumetric distance field and beta growth function , 2015 .