Control of Two-Section 3D Printed Tele-operated Wire-Driven Continuum Robot Arm
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Abstract
In the last couple of decades, wire-driven mechanisms getting more attention in robotics and medical instruments. The wire-driven actuation system is one of the effective ways of force transmission in the distance. In continuum robots, a wire-driven mechanism plays a crucial role in robot control. Likewise, power transmission in a range allows us to locate motors in the base and improve robot design and dexterity features as well. However, a wire-driven mechanism cannot provide stiffness to the robot structure, which can negatively affect the robot's end-effector position. Therefore, many scholars and engineers contributing various types of continuum robot’s backbone design to provide necessary rigidity to the robot backbone during the work. Also, wire-driven mechanisms have a problem with tension control. Tendon actuated robots demand additional mechanisms to compensate for lost tension during the motion as well. So, the investigation will cover a novel pretension mechanism system to avoid wire slack and escape from the pulleys. The novelty of this research is proposed by robot kinematics and a new robot control strategy.This research will describe a continuum robot backbone design and robot control, moreover, based on proposed robot design, forward kinematics, and control architecture of the robot.
Keywords
Continuum robot, wire-driven, 3d printed, robot design, control, kinematics.
Cite this paper
Azamat Yeshmukhametov, Koichi Koganezawa, Askar Seidakhmet, Yoshio Yamamoto,
Control of Two-Section 3D Printed Tele-operated Wire-Driven Continuum Robot Arm
, SCIREA Journal of Electrical Engineering.
Volume 5, Issue 1, February 2020 | PP. 1-19.
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