Fold Mechanics of Natural and Synthetic Origami Papers
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To realize engineered materials and structures via origami methods and other folding construction techniques, fundamental understanding of paper folding mechanics and their dependency on paper micro/nanostructure is needed. Using selected papers commonly used in origami designs, we establish the relationship between the mechanical properties of fibrous paper and their corresponding ability to form and retain simple creases and mountain/valley folds. Using natural fiber paper (abaca), synthetic fiber paper (Tyvek), and a metalfiber laminate paper, we studied how the fold radius depends on the load applied using a controlled rolling apparatus. After folding, we examined the resultant micro- and nanoscale deformation using electron microscopy. In general we found that the fold radius follows a power law, decreasing with the applied rolling force. At a critical strain, each paper exhibits a transition between elastic and plastic behavior, after which the trend asymptotically approaches the minimum fold radius with increased applied force. Finally, we present examples of centimeter-scale two-dimensionally "mountain fold" patterns and relate the folding characteristics observed in these designs to the mechanical properties of the papers in folding. Keywords: Deformation; Fibers; Synthetic fibers; Laminates; Electron microscopy; Metal fibers; Construction; Stress; Mechanical properties; Nanoscale phenomena
Date issued
2013-08Department
Massachusetts Institute of Technology. Department of Mechanical EngineeringJournal
Volume 6B: 37th Mechanisms and Robotics Conference
Publisher
ASME International
Citation
Rao, Abhinav et al. “Fold Mechanics of Natural and Synthetic Origami Papers.” Volume 6B: 37th Mechanisms and Robotics Conference, August 4-7 2013, Portland, Oregon, USA, American Society of Mechanical Engineers, August 2013. © 2013 ASME
Version: Final published version