Author_Institution :
Massachusetts Inst. of Technol., Cambridge, MA, USA
Abstract :
This research involves the design, manufacture, and testing of a small, <1 m3, <10 kg, low cost, unmanned submersible. High maneuverability in the ROV as achieved through a high thrust-to-mass ratio in all directions. One identified solution is moving the primary thrusters in both the pitch and yaw directions. The robot is propelled by a pair of 2 DOF thrusters, and is directly controlled in heave, surge, sway, yaw, and roll. Pitch is controlled through passive buoyancy and active manipulation of added mass and gyroscopic effects. This system is compared against a traditional fixed-thruster system in terms of cost, size, weight, and high/low speed performance. Preliminary results indicate that the actuated system can provide an improved thrust-to-mass metric at the expense of increased system complexity. The system has applications in high accuracy positioning areas such as ship hull inspection, recovery, and exploration.
Keywords :
mobile robots; navigation; propellers; remotely operated vehicles; underwater vehicles; DOF thrusters; ROV maneuverability; dual articulating thrusters; low cost unmanned submersible; maneuverable remotely operated vehicle; passive buoyancy; pitch direction; robot propelling; ship hull inspection; system complexity; thrust-to-mass metric; vehicle design; vehicle testing; yaw direction; Costs; Manufacturing; Marine vehicles; Propulsion; Remotely operated vehicles; Robots; Surges; Testing; Underwater vehicles; Weight control;
