Reconfigurable foot-to-gripper leg for underwater bottom operator, Hexaquad

This paper presents the development of a configurable leg-to-arm for configurable robot, named Hexapod-to-Quadruped (Hexaquad) robot, which is designed and developed for riverbed/seabed exploration and related works. Reconfigurable legged robot, one of robotics research areas, is generally focused on optimizing the usage of leg during locomotion. Until recently, most of the researches have emphasized on leg reconfigurable design in order to solve issues related to fault tolerant, stability, multitasking and energy efficiency. However, the emphasis of Hexaquad robot is on providing optimum leg usage, actuation configuration as well as satisfying the legged robot stability criterion in reconfiguration mechanism. Inspired by foot-to-gripper (FTG) transformation of crab chelipads, each leg of the proposed Hexaquad robot have mass affect avoidance. The minimum torque on each leg joint is calculated as well as FTG using static torque calculation on multi-link structure before selecting the actuator/motor. Performance tests are done by performing fundamental testing on optimum standing posture, stress and displacement analysis on FTG model, including gripping tests to several shapes of objects both in the air and underwater environment.

[1]  Samuel N. Cubero,et al.  Design Concepts for a Hybrid Swimming and Walking Vehicle , 2012 .

[2]  Andrew Hogue,et al.  AQUA: An Amphibious Autonomous Robot , 2007, Computer.

[3]  Aaron M. Dollar,et al.  Kinematic Design of an Underactuated Robot Leg for Passive Terrain Adaptability and Stability , 2013 .

[4]  Junichi Akizono,et al.  Field Test of Aquatic Walking Robot for Underwater Inspection , 1990 .

[5]  Yi Sun,et al.  Modules Design of a Reconfigurable Multi-Legged Walking Robot , 2006, 2006 IEEE International Conference on Robotics and Biomimetics.

[6]  Addie Irawan,et al.  Control input converter for robot's leg joint with parallel actuation configuration , 2014, 8th International Conference on Electrical and Computer Engineering.

[7]  Pere Ridao,et al.  Grasping for the Seabed: Developing a New Underwater Robot Arm for Shallow-Water Intervention , 2013, IEEE Robotics & Automation Magazine.

[8]  Jung-Min Yang Fault-Tolerant Gait Planning for a Hexapod Robot Walking over Rough Terrain , 2009, J. Intell. Robotic Syst..

[9]  Addie Irawan,et al.  Optimizing Hexapod Robot Reconfiguration using Hexa-Quad Transformation , 2014, ICRA 2014.

[10]  Kenneth J. Waldron,et al.  Machines That Walk: The Adaptive Suspension Vehicle , 1988 .

[11]  J. S. Smith,et al.  Docking techniques and evaluation trials of the SWIMMER AUV: an autonomous deployment AUV for work-class ROVs , 2001, MTS/IEEE Oceans 2001. An Ocean Odyssey. Conference Proceedings (IEEE Cat. No.01CH37295).

[12]  Marc H. Raibert,et al.  Legged Robots That Balance , 1986, IEEE Expert.

[13]  Kenzo Nonami,et al.  Hydraulically Actuated Hexapod Robots , 2014 .

[14]  Andrew Hogue,et al.  AQUA: an aquatic walking robot , 2004, 2004 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS) (IEEE Cat. No.04CH37566).

[15]  Kenzo Nonami,et al.  Hydraulically Actuated Hexapod Robots: Design, Implementation and Control , 2013 .

[16]  J. Akizono,et al.  Seabottom roughness measurement by aquatic walking robot , 1997, Oceans '97. MTS/IEEE Conference Proceedings.

[17]  Philip Holmes,et al.  Stability Analysis of a Clock-Driven Rigid-Body SLIP Model for RHex , 2004, Int. J. Robotics Res..

[18]  C. Waldmann,et al.  Exploration of underwater structures with cooperative heterogeneous robots , 2005, Europe Oceans 2005.

[19]  Bong-Huan Jun,et al.  Development of seabed walking robot CR200 , 2013, 2013 MTS/IEEE OCEANS - Bergen.