FlexTruss: A Computational Threading Method for Multi-material, Multi-form and Multi-use Prototyping

3D printing, as a rapid prototyping technique, usually fabricates objects that are difficult to modify physically. This paper presents FlexTruss, a design and construction pipeline based on the assembly of modularized truss-shaped objects fabricated with conventional 3D printers and assembled by threading. To create an end-to-end system, a parametric design tool with an optimal Euler path calculation method is developed, which can support both inverse and forward design workflow and multi-material construction of modular parts. In addition, the assembly of truss modules by threading is evaluated with a series of application cases to demonstrate the affordance of FlexTruss. We believe that FlexTruss extends the design space of 3D printing beyond typically hard and fixed forms, and it will provide new capabilities for designers and researchers to explore the use of such flexible truss structures in human-object interaction.

[1]  Joseph A. Paradiso,et al.  ChainFORM: A Linear Integrated Modular Hardware System for Shape Changing Interfaces , 2016, UIST.

[2]  Alec Jacobson RodSteward: A Design‐to‐Assembly System for Fabrication using 3D‐Printed Joints and Precision‐Cut Rods , 2019, Comput. Graph. Forum.

[3]  Bernhard Thomaszewski,et al.  Designing structurally-sound ornamental curve networks , 2016, ACM Trans. Graph..

[4]  Eder Miguel,et al.  Computational design of stable planar-rod structures , 2016, ACM Trans. Graph..

[5]  Pedro Lopes,et al.  TrussFormer: 3D Printing Large Kinetic Structures , 2018, UIST.

[6]  Chi-Wing Fu,et al.  Fabricable eulerian wires for 3D shape abstraction , 2018, ACM Trans. Graph..

[7]  Markus H. Gross,et al.  A computational design tool for compliant mechanisms , 2017, ACM Trans. Graph..

[8]  Joseph A. Paradiso,et al.  Augmented Airbrush for Computer Aided Painting (CAP) , 2015, TOGS.

[9]  David E. Breen,et al.  Geodesy: Self-rising 2.5D Tiles by Printing along 2D Geodesic Closed Path , 2019, CHI.

[10]  Levent Burak Kara,et al.  4DMesh: 4D Printing Morphing Non-Developable Mesh Surfaces , 2018, UIST.

[11]  Robert Kovacs,et al.  TrussFab: Fabricating Sturdy Large-Scale Structures on Desktop 3D Printers , 2017, CHI.

[12]  Kimiko Ryokai,et al.  Being the Machine: Reconfiguring Agency and Control in Hybrid Fabrication , 2015, CHI.

[13]  Mark D. Gross,et al.  Interactive fabrication: new interfaces for digital fabrication , 2010, TEI.

[14]  Steve Marschner,et al.  Printing arbitrary meshes with a 5DOF wireframe printer , 2016, ACM Trans. Graph..

[15]  Amit Zoran,et al.  Hybrid Basketry: Interweaving Digital Practice within Contemporary Craft , 2013, Leonardo.

[16]  Miguel Bruns Alonso,et al.  Exploring mechanical meta-material structures through personalised shoe sole design , 2019, SCF.

[17]  Steve Marschner,et al.  On-The-Fly Print: Incremental Printing While Modelling , 2016, CHI.

[18]  Patrick Baudisch,et al.  RoMA: Interactive Fabrication with Augmented Reality and a Robotic 3D Printer , 2018, CHI.

[19]  Guanyun Wang,et al.  A-line: 4D Printing Morphing Linear Composite Structures , 2019, CHI.

[20]  Madeline Gannon,et al.  ExoSkin: On-Body Fabrication , 2016, CHI.

[21]  Eitan Grinspun,et al.  Designing inflatable structures , 2014, ACM Trans. Graph..

[22]  Robert Kovacs,et al.  Digital Mechanical Metamaterials , 2017, CHI.

[23]  Guanyun Wang,et al.  Printed Paper Actuator: A Low-cost Reversible Actuation and Sensing Method for Shape Changing Interfaces , 2018, CHI.

[24]  Daniel Cohen-Or,et al.  Connected fermat spirals for layered fabrication , 2016, ACM Trans. Graph..

[25]  Amit Zoran,et al.  D-Coil: A Hands-on Approach to Digital 3D Models Design , 2015, CHI.

[26]  Joseph A. Paradiso,et al.  FreeD: a freehand digital sculpting tool , 2013, CHI.

[27]  Guanyun Wang,et al.  Inverse Design Tool for Asymmetrical Self-Rising Surfaces with Color Texture , 2020, SCF.

[28]  Haruki Takahashi,et al.  3D Pen + 3D Printer: Exploring the Role of Humans and Fabrication Machines in Creative Making , 2019, CHI.

[29]  Stefanie Müller,et al.  WirePrint: 3D printed previews for fast prototyping , 2014, UIST.

[30]  Ligang Liu,et al.  FrameFab: robotic fabrication of frame shapes , 2016, ACM Trans. Graph..

[31]  Robert Kovacs,et al.  Protopiper: Physically Sketching Room-Sized Objects at Actual Scale , 2015, UIST.

[32]  Loe Feijs,et al.  Sole maker : towards ultra-personalised shoe design using voronoi diagrams and 3D printing , 2016 .

[33]  David Lindlbauer,et al.  Understanding Metamaterial Mechanisms , 2019, CHI.

[34]  Christos H. Papadimitriou,et al.  On the complexity of edge traversing , 1976, J. ACM.

[35]  Patrick Baudisch,et al.  faBrickation: fast 3D printing of functional objects by integrating construction kit building blocks , 2014, CHI.

[36]  Xiang 'Anthony' Chen,et al.  Medley: A Library of Embeddables to Explore Rich Material Properties for 3D Printed Objects , 2018, CHI.

[37]  Hans-Werner Gellersen,et al.  ReForm: Integrating Physical and Digital Design through Bidirectional Fabrication , 2015, UIST.

[38]  Katsuhiro Hata,et al.  Soft yet Strong Inflatable Structures for a Foldable and Portable Mobility , 2020, CHI Extended Abstracts.

[39]  Hiroshi Ishii,et al.  LineFORM: Actuated Curve Interfaces for Display, Interaction, and Constraint , 2015, UIST.

[40]  Cheng Yao,et al.  WeaveMesh: A Low-Fidelity and Low-Cost Prototyping Approach for 3D Models Created by Flexible Assembly , 2017, CHI.

[41]  Kris Luyten,et al.  StrutModeling: A Low-Fidelity Construction Kit to Iteratively Model, Test, and Adapt 3D Objects , 2017, UIST.

[42]  Guanyun Wang,et al.  4DTexture: A Shape-Changing Fabrication Method for 3D Surfaces with Texture , 2020, CHI Extended Abstracts.

[43]  Stefanie Müller,et al.  Platener: Low-Fidelity Fabrication of 3D Objects by Substituting 3D Print with Laser-Cut Plates , 2015, CHI.