Kinetogami: A Reconfigurable, Combinatorial, and Printable Sheet Folding

As an ancient paper craft originating from Japan, origami has been naturally embedded and contextualized in a variety of applications in the fields of mathematics, engineering, food packaging, and biological design. The computational and manufacturing capabilities today urge us to develop significantly new forms of folding as well as different materials for folding. In this paper, by allowing line cuts with crease patterns and creating folded hinges across basic structural units (BSU), typically not done in origami, we achieve a new multiprimitive folding framework such as using tetrahedral, cuboidal, prismatic, and pyramidal components, called “Kinetogami.” “Kinetogami” enables one to fold up closed-loop(s) polyhedral mechanisms (linkages) with multi-degree-of-freedom and self-deployable characteristics in a single build. This paper discusses a set of mathematical and design theories to enable design of 3D structures and mechanisms all folded from preplanned printed sheet materials. We present prototypical exploration of folding polyhedral mechanisms in a hierarchical manner as well as their transformations through reconfiguration that reorients the material and structure. The explicit 2D fabrication layout and construction rules are visually parameterized for geometric properties to ensure a continuous folding motion free of intersection. As a demonstration artifact, a multimaterial sheet is 3D printed with elastomeric flexure hinges connecting the rigid plastic facets. [DOI: 10.1115/1.4025506]

[1]  Karthik Ramani,et al.  Reconfigurable Foldable Spatial Mechanisms and Robotic Forms Inspired by Kinetogami , 2012 .

[2]  Erik D. Demaine,et al.  Programmable Assembly With Universally Foldable Strings (Moteins) , 2011, IEEE Transactions on Robotics.

[3]  Glen Mullineux,et al.  Using constraints at the conceptual stage of the design of carton erection , 2010 .

[4]  Andrei M. Shkel,et al.  Chip-scale IMU using folded-mems approach , 2010, 2010 IEEE Sensors.

[5]  H Tanaka,et al.  Programmable matter by folding , 2010, Proceedings of the National Academy of Sciences.

[6]  Alastair Johnson,et al.  Mechanical tests for foldcore base material properties , 2009 .

[7]  Koryo Miura,et al.  The Science of Miura-Ori: A Review , 2009 .

[8]  Iuliu Vasilescu,et al.  Miche: Modular Shape Formation by Self-Disassembly , 2008, Proceedings 2007 IEEE International Conference on Robotics and Automation.

[9]  Erik D. Demaine,et al.  Hinged Dissection of Polypolyhedra , 2005, WADS.

[10]  Zhong You,et al.  Threefold-symmetric Bricard linkages for deployable structures , 2005 .

[11]  Nicholas G. Dagalakis,et al.  Analysis and design of parallel mechanisms with flexure joints , 2004, IEEE Transactions on Robotics.

[12]  Joseph B. M. Mitchell,et al.  When can you fold a map? , 2000, Comput. Geom..

[13]  David Eppstein,et al.  Hinged dissections of polyominoes and polyforms , 1999, CCCG.

[14]  Joseph S. B. Mitchell,et al.  Folding flat silhouettes and wrapping polyhedral packages: new results in computational origami , 1999, SCG '99.

[15]  G. Anderson Surgery with Coefficients , 1977 .

[16]  Zhong You,et al.  Spatial Overconstrained Linkages—The Lost Jade , 2012 .

[17]  Matt A. King,et al.  Three-Dimensional Structures Self-Assembled from DNA Bricks , 2012 .

[18]  George W. Hart,et al.  Modular Kirigami , 2007 .

[19]  Charlotte Kessler,et al.  Multimodular Origami Polyhedra: Archimedeans, Buckyballs, and Duality (Book) , 2004 .

[20]  J.Eddie Baker,et al.  An analysis of the Bricard linkages , 1980 .