Peano-HASEL actuators: Muscle-mimetic, electrohydraulic transducers that linearly contract on activation

A class of fast, muscle-mimetic actuators uses electrohydraulic coupling to linearly contract on activation. Soft robotic systems are well suited to unstructured, dynamic tasks and environments, owing to their ability to adapt and conform without damaging themselves or their surroundings. These abilities are crucial in areas such as human-robot interaction. Soft robotic systems are currently limited by the soft actuators that power them. To date, most soft actuators are based on pneumatics or shape-memory alloys, which have issues with efficiency, response speed, and portability. Dielectric elastomer actuators (DEAs) are controlled and powered electrically and excel with muscle-like actuation, but they typically require a rigid frame and prestretch to perform effectively. In addition, DEAs require complex stacks or structures to achieve linear contraction modes. We present a class of soft electrohydraulic transducers, termed Peano-HASEL (hydraulically amplified self-healing electrostatic) actuators, that combine the strengths of fluidic actuators and electrostatic actuators, while addressing many of their issues. These actuators use both electrostatic and hydraulic principles to linearly contract on application of voltage in a muscle-like fashion, without rigid frames, prestretch, or stacked configurations. We fabricated these actuators using a facile heat-sealing method with inexpensive commercially available materials. These prototypical devices demonstrated controllable linear contraction up to 10%, a strain rate of 900% per second, actuation at 50 hertz, and the ability to lift more than 200 times their weight. In addition, these actuators featured characteristics such as high optical transparency and the ability to self-sense their deformation state. Hence, this class of actuators demonstrates promise for applications such as active prostheses, medical and industrial automation, and autonomous robotic devices.

[1]  G. Whitesides,et al.  Buckling Pneumatic Linear Actuators Inspired by Muscle , 2016 .

[2]  Alexandre Poulin,et al.  Flexible Zinc–Tin Oxide Thin Film Transistors Operating at 1 kV for Integrated Switching of Dielectric Elastomer Actuators Arrays , 2017, Advanced materials.

[3]  Suresh V. Garimella,et al.  Analytical model for an electrostatically actuated miniature diaphragm compressor , 2008 .

[4]  D. De Rossi,et al.  Hydrostatically Coupled Dielectric Elastomer Actuators , 2010, IEEE/ASME Transactions on Mechatronics.

[5]  Tingyu Cheng,et al.  Fast-moving soft electronic fish , 2017, Science Advances.

[6]  Robert J. Wood,et al.  An integrated design and fabrication strategy for entirely soft, autonomous robots , 2016, Nature.

[7]  Siegfried Bauer,et al.  Capacitive extensometry for transient strain analysis of dielectric elastomer actuators , 2008 .

[8]  M. Sitti,et al.  Soft Actuators for Small‐Scale Robotics , 2017, Advanced materials.

[9]  Zhigang Suo,et al.  Transparent hydrogel with enhanced water retention capacity by introducing highly hydratable salt , 2014 .

[10]  Shane K. Mitchell,et al.  Hydraulically amplified self-healing electrostatic actuators with muscle-like performance , 2018, Science.

[11]  Mihai Duduta,et al.  Multilayer Dielectric Elastomers for Fast, Programmable Actuation without Prestretch , 2016, Advanced materials.

[12]  Iain A. Anderson,et al.  Dielectric elastomer switches for smart artificial muscles , 2010 .

[13]  Q. Pei,et al.  Advances in dielectric elastomers for actuators and artificial muscles. , 2010, Macromolecular rapid communications.

[14]  Bryan M. Wong,et al.  A Transparent, Self‐Healing, Highly Stretchable Ionic Conductor , 2016, Advanced materials.

[15]  Z. Suo Theory of dielectric elastomers , 2010 .

[16]  Iain A. Anderson,et al.  The smart Peano fluidic muscle: a low profile flexible orthosis actuator that feels pain , 2015, Smart Structures.

[17]  Andrey V. Dobrynin,et al.  Bottlebrush Elastomers: A New Platform for Freestanding Electroactuation , 2017, Advanced materials.

[18]  Sanlin S. Robinson,et al.  Highly stretchable electroluminescent skin for optical signaling and tactile sensing , 2016, Science.

[19]  O. Schmitt The heat of shortening and the dynamic constants of muscle , 2017 .

[20]  Nikolaos G. Tsagarakis,et al.  Water/air performance analysis of a fluidic muscle , 2010, 2010 IEEE/RSJ International Conference on Intelligent Robots and Systems.

[21]  Xuanhe Zhao,et al.  Hydraulic hydrogel actuators and robots optically and sonically camouflaged in water , 2017, Nature Communications.

[22]  Ephrahim Garcia,et al.  Reconsidering the McKibben muscle: Energetics, operating fluid, and bladder material , 2014 .

[23]  Daniela Rus,et al.  Pouch Motors: Printable/inflatable soft actuators for robotics , 2014, 2014 IEEE International Conference on Robotics and Automation (ICRA).

[24]  Stephen A. Morin,et al.  Soft Robotics: Review of Fluid‐Driven Intrinsically Soft Devices; Manufacturing, Sensing, Control, and Applications in Human‐Robot Interaction   , 2017 .

[25]  Samuel Rosset,et al.  Small, fast, and tough: Shrinking down integrated elastomer transducers , 2016 .

[26]  Jeffrey H. Lang,et al.  Optimum Design of an Electrostatic Zipper Actuator , 2004 .

[27]  Rachel Z. Pytel,et al.  Artificial muscle technology: physical principles and naval prospects , 2004, IEEE Journal of Oceanic Engineering.

[28]  Choon Chiang Foo,et al.  Stretchable, Transparent, Ionic Conductors , 2013, Science.

[29]  Cecilia Laschi,et al.  Soft robotics: a bioinspired evolution in robotics. , 2013, Trends in biotechnology.

[30]  Robert J. Wood,et al.  A Resilient, Untethered Soft Robot , 2014 .

[31]  I. Hunter,et al.  A comparison of muscle with artificial actuators , 1992, Technical Digest IEEE Solid-State Sensor and Actuator Workshop.

[32]  Siddharth Sanan,et al.  Pneumatic Torsional Actuators for Inflatable Robots , 2014 .

[33]  S. Michel,et al.  Stacked dielectric elastomer actuator for tensile force transmission , 2009 .

[34]  Xiangyang Zhu,et al.  A survey on dielectric elastomer actuators for soft robots , 2017, Bioinspiration & biomimetics.

[35]  Sheng Quan Xie,et al.  Characterizing the Peano fluidic muscle and the effects of its geometry properties on its behavior , 2016 .

[36]  Filip Ilievski,et al.  Soft robotics for chemists. , 2011, Angewandte Chemie.

[37]  Dirk Lefeber,et al.  Pneumatic artificial muscles: Actuators for robotics and automation , 2002 .

[38]  T. Lebey,et al.  Dielectric breakdown of polyimide films: Area, thickness and temperature dependence , 2010, IEEE Transactions on Dielectrics and Electrical Insulation.

[39]  Q. Pei,et al.  High-speed electrically actuated elastomers with strain greater than 100% , 2000, Science.

[40]  Xuanhe Zhao,et al.  Skin-inspired hydrogel–elastomer hybrids with robust interfaces and functional microstructures , 2016, Nature Communications.

[41]  Qibing Pei,et al.  Synthesizing a new dielectric elastomer exhibiting large actuation strain and suppressed electromechanical instability without prestretching , 2013 .

[42]  Allison M. Okamura,et al.  A soft robot that navigates its environment through growth , 2017, Science Robotics.

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

[44]  Yuanyuan Li,et al.  A paper-based electrostatic zipper actuator for printable robots , 2014, 2014 IEEE International Conference on Robotics and Automation (ICRA).

[45]  Janet Ho,et al.  Characterization of High Temperature Polymer Thin Films for Power Conditioning Capacitors , 2009 .

[46]  H. Shea,et al.  Zipping dielectric elastomer actuators: characterization, design and modeling , 2013 .