Lightweight High Voltage Generator for Untethered Electroadhesive Perching of Micro Air Vehicles

The limited in-flight battery lifetime of centimeter-scale flying robots is a major barrier to their deployment, especially in applications which take advantage of their ability to reach high vantage points. Perching, where flyers remain fixed in space without use of flight actuators by attachment to a surface, is a potential mechanism to overcome this barrier. Electroadhesion, a phenomenon where an electrostatic force normal to a surface is generated by induced charge, has been shown to be an increasingly viable perching mechanism as robot size decreases due to the increased surface-area-to-volume ratio. Typically electroadhesion requires high ($>\!1$ kV) voltages to generate useful forces, leading to relatively large power supplies that cannot be carried on-board a micro air vehicle. In this letter, we motivate the need for application-specific power electronics solutions for electroadhesive perching, develop a useful figure of merit (the “specific voltage”) for comparing and guiding efforts, and walk through the design methodology of a system implementation. We conclude by showing that this high voltage power supply enables, for the first time in the literature, tetherless electroadhesive perching of a commercial micro quadrotor.

[1]  Daniela Rus,et al.  Multi-robot path planning for a swarm of robots that can both fly and drive , 2017, 2017 IEEE International Conference on Robotics and Automation (ICRA).

[2]  Gareth J. Monkman An Analysis of Astrictive Prehension , 1997, Int. J. Robotics Res..

[3]  Christoph Hürzeler,et al.  A perching mechanism for micro aerial vehicles , 2009 .

[4]  Robert J. Wood,et al.  Controlled flight of a microrobot powered by soft artificial muscles , 2019, Nature.

[5]  Gareth J. Monkman Electroadhesive microgrippers , 2003, Ind. Robot.

[6]  Xiangyang Zhu,et al.  Soft wall-climbing robots , 2018, Science Robotics.

[7]  Juan Rivas-Davila,et al.  Duty Cycle and Frequency Modulations in Class-E DC–DC Converters for a Wide Range of Input and Output Voltages , 2018, IEEE Transactions on Power Electronics.

[8]  S. G. Ponnambalam,et al.  Modeling and simulation of Electrostatic Adhesion for Wall Climbing Robot , 2011, 2011 IEEE International Conference on Robotics and Biomimetics.

[9]  Robert C. Michelson,et al.  Overview of Micro Air Vehicle System Design and Integration Issues , 2010 .

[10]  Aaron M. Harrington,et al.  Power and weight considerations in small, agile quadrotors , 2014, Defense + Security Symposium.

[11]  R. Wood,et al.  Perching and takeoff of a robotic insect on overhangs using switchable electrostatic adhesion , 2016, Science.

[12]  Grasp Lab AVIAN-INSPIRED GRASPING FOR QUADROTOR MICRO UAVS , 2013 .

[13]  Roy Kornbluh,et al.  Electroadhesive robots—wall climbing robots enabled by a novel, robust, and electrically controllable adhesion technology , 2008, 2008 IEEE International Conference on Robotics and Automation.

[14]  D. Pines,et al.  Challenges Facing Future Micro-Air-Vehicle Development , 2006 .

[15]  Karsten Berns,et al.  Omnidirectional locomotion and traction control of the wheel-driven, wall-climbing robot, Cromsci , 2011, Robotica.

[16]  Mingjing Qi,et al.  Electrostatic flapping wings with pivot-spar brackets for high lift force , 2016, 2016 IEEE 29th International Conference on Micro Electro Mechanical Systems (MEMS).

[17]  M. Sreekumar,et al.  Experimental Investigation of the Effect of the Driving Voltage of an Electroadhesion Actuator , 2014, Materials.

[18]  Robert J. Wood,et al.  Progress on "Pico" Air Vehicles , 2011, ISRR.

[19]  Todd Hylton,et al.  The DARPA Nano Air Vehicle Program , 2012 .

[20]  Riccardo Rovatti,et al.  An Analytical Approach for the Design of Class-E Resonant DC–DC Converters , 2016, IEEE Transactions on Power Electronics.

[21]  Kristofer S. J. Pister,et al.  Toward Controlled Flight of the Ionocraft: A Flying Microrobot Using Electrohydrodynamic Thrust With Onboard Sensing and No Moving Parts , 2018, IEEE Robotics and Automation Letters.

[22]  Luca Petricca,et al.  Micro- and Nano-Air Vehicles: State of the Art , 2011 .

[23]  Jonathan Rossiter,et al.  Electro-ribbon actuators and electro-origami robots , 2018, Science Robotics.

[24]  Robert J. Wood,et al.  Science, technology and the future of small autonomous drones , 2015, Nature.

[25]  Neel Doshi,et al.  Inverted and vertical climbing of a quadrupedal microrobot using electroadhesion , 2018, Science Robotics.

[26]  Jianglong Guo,et al.  Elastic Electroadhesion with Rapid Release by Integrated Resonant Vibration , 2018, Advanced Materials Technologies.

[27]  Mats Jackson,et al.  Optimization and experimental verification of coplanar interdigital electroadhesives , 2016 .

[28]  Qianhong Chen,et al.  GaN VHF Converters With Integrated Air-Core Transformers , 2019, IEEE Transactions on Power Electronics.

[29]  Robert J. Wood,et al.  Sensors and Actuators A: Physical , 2009 .

[30]  D. F. Kostishack,et al.  Micro Air Vehicles for Optical Surveillance , 1999 .

[31]  D.V.Razevig High voltage engineering , 2006, 2006 Eleventh International Middle East Power Systems Conference.

[32]  Juan Rivas-Davila,et al.  Miniature High-Voltage DC-DC Power Converters for Space and Micro-Robotic Applications , 2019, 2019 IEEE Energy Conversion Congress and Exposition (ECCE).

[33]  Metin Sitti,et al.  A miniature ceiling walking robot with flat tacky elastomeric footpads , 2009, 2009 IEEE International Conference on Robotics and Automation.

[34]  David J. Perreault,et al.  Flight of an aeroplane with solid-state propulsion , 2018, Nature.

[35]  P. M. Taylor,et al.  PRINCIPLES OF ELECTROADHESION IN CLOTHING ROBOTICS , 1989 .

[36]  Kristofer S. J. Pister,et al.  First steps of a millimeter-scale walking silicon robot , 2017, 2017 19th International Conference on Solid-State Sensors, Actuators and Microsystems (TRANSDUCERS).

[37]  Robert J. Wood,et al.  Untethered flight of an insect-sized flapping-wing microscale aerial vehicle , 2019, Nature.