ModiFiber: Two-Way Morphing Soft Thread Actuators for Tangible Interaction

Despite thin-line actuators becoming widely adopted in different Human-Computer Interaction (HCI) contexts, including integration into fabrics, paper art, hinges, soft robotics, and human hair, accessible line-based actuators are very limited beyond shape memory alloy (SMA) wire and motor-driven passive tendons. In this paper, we introduce a novel, yet simple and accessible, line-based actuator. ModiFiber is a twisted-then-coiled nylon thread actuator with a silicone coating. This composite thread actuator exhibits unique two-way reversible shrinking or twisting behaviors triggered by heat or electrical current (i.e., Joule heating). ModiFiber is soft, flexible, safe to operate and easily woven or sewn, hence it has a great potential as an embedded line-based actuator for HCI purposes. In this paper, we explain the material mechanisms and manufacturing approaches, followed by some performance tests and application demonstrations.

[1]  Hugh R. Brown,et al.  Characterisation of torsional actuation in highly twisted yarns and fibres , 2015 .

[2]  Soheil Kianzad A treatise on highly twisted artificial muscle : thermally driven shape memory alloy yarn and coiled nylon actuators , 2015 .

[3]  R. Baughman Conducting polymer artificial muscles , 1996 .

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

[5]  Yonas Tadesse,et al.  Fully embedded actuators in elastomeric skin for use in humanoid robots , 2018, Smart Structures and Materials + Nondestructive Evaluation and Health Monitoring.

[6]  E. Smela Conjugated Polymer Actuators for Biomedical Applications , 2003 .

[7]  S. John,et al.  Power-efficient low-temperature woven coiled fibre actuator for wearable applications , 2016, Scientific Reports.

[8]  Hiroshi Ishii,et al.  Jamming user interfaces: programmable particle stiffness and sensing for malleable and shape-changing devices , 2012, UIST.

[9]  Yonas Tadesse,et al.  Fabrication Parameters and Performance Relationship of Twisted and Coiled Polymer Muscles , 2016 .

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

[11]  Aleksandr N. Semochkin A device for producing artificial muscles from nylon fishing line with a heater wire , 2016, 2016 IEEE International Symposium on Assembly and Manufacturing (ISAM).

[12]  Jie Qi,et al.  Animating paper using shape memory alloys , 2012, CHI.

[13]  Seon Jeong Kim,et al.  Lima Tensile Actuation of Hybrid Carbon Nanotube Yarn Muscles Electrically , Chemically , and Photonically Powered Torsional and , 2012 .

[14]  Pattie Maes,et al.  Shutters: a permeable surface for environmental control and communication , 2009, TEI.

[15]  Majken Kirkegaard Rasmussen,et al.  Shape-changing interfaces: a review of the design space and open research questions , 2012, CHI.

[16]  Yasuaki Kakehi,et al.  Organic Primitives: Synthesis & Design of pH-Reactive Material InterfacesMaterials with Organic Molecules for Biocompatible I/O , 2016, ArXiv.

[17]  Mark D. Gross,et al.  Interactive paper devices: end-user design & fabrication , 2010, TEI '10.

[18]  Hiroshi Ishii,et al.  bioLogic: Natto Cells as Nanoactuators for Shape Changing Interfaces , 2015, CHI.

[19]  Hiroshi Ishii,et al.  aeroMorph - Heat-sealing Inflatable Shape-change Materials for Interaction Design , 2016, UIST.

[20]  Hiroshi Ishii,et al.  Organic Primitives: Synthesis and Design of pH-Reactive Materials using Molecular I/O for Sensing, Actuation, and Interaction , 2016, CHI.

[21]  Yonas Tadesse,et al.  Modeling of twisted and coiled polymer (TCP) muscle based on phenomenological approach , 2017 .

[22]  M. Maugey,et al.  Shape and Temperature Memory of Nanocomposites with Broadened Glass Transition , 2007, Science.

[23]  Lucy E. Dunne,et al.  Active "hugging" vest for deep touch pressure therapy , 2016, UbiComp Adjunct.

[24]  Carter S. Haines,et al.  Artificial Muscles from Fishing Line and Sewing Thread , 2014, Science.

[25]  A. Concas,et al.  Knitting and weaving artificial muscles , 2017, Science Advances.

[26]  Hiroshi Ishii,et al.  Printflatables: Printing Human-Scale, Functional and Dynamic Inflatable Objects , 2017, CHI.

[27]  Michael W. Shafer,et al.  A Novel Biomimetic Torsional Actuator Design Using Twisted Polymer Actuators , 2017 .

[28]  Ian Hunter,et al.  The application of conducting polymers to a biorobotic fin propulsor , 2007, Bioinspiration & biomimetics.

[29]  Eric Paulos,et al.  HäirIÖ: Human Hair as Interactive Material , 2018, Tangible and Embedded Interaction.

[30]  Hiroshi Ishii,et al.  PneUI: pneumatically actuated soft composite materials for shape changing interfaces , 2013, UIST.

[31]  Hiroshi Ishii,et al.  Transformative Appetite: Shape-Changing Food Transforms from 2D to 3D by Water Interaction through Cooking , 2017, CHI.

[32]  Mehmet Zahit Bilir,et al.  Shape-Memory Applications in Textile Design☆ , 2015 .

[33]  Rainer Groh,et al.  HCI meets Material Science: A Literature Review of Morphing Materials for the Design of Shape-Changing Interfaces , 2018, CHI.

[34]  Markus Löchtefeld,et al.  Morphees: toward high "shape resolution" in self-actuated flexible mobile devices , 2013, CHI.