Title :
Anisotropic Patterning to Reduce Instability of Concentric-Tube Robots
Author :
Dae-Young Lee ; Jongwoo Kim ; Ji-Suk Kim ; Changyeob Baek ; Gunwoo Noh ; Do-Nyun Kim ; Keri Kim ; Sungchul Kang ; Kyu-Jin Cho
Author_Institution :
Dept. of Mech. & Aerosp. Eng., Seoul Nat. Univ., Seoul, South Korea
Abstract :
As a steerable needle or robotic manipulator, the concentric-tube robot shows good potential for use in minimally invasive medical procedures. However, the torsional deformation of the precurved tubes comes at the price of instability, which not only limits the workspace and tool path but also potentially creates danger of tissue rupture when external load is applied. In this paper, we propose anisotropic patterning of tubes to solve the instability problem. Hole-patterning can tune the mechanical properties of the tubes so that the ratio of the torsional rigidity to the bending rigidity becomes higher. This study investigates the effect of pattern design parameters by building a lumped analytical model and examining it with finite-element analysis. The pattern is engraved via laser machining and we experimentally verify that material anisotropy reduces instability.
Keywords :
bending; biological tissues; dexterous manipulators; finite element analysis; fracture; laser beam machining; medical robotics; pipes; shear modulus; torsion; anisotropic patterning; bending rigidity; concentric-tube robot; external load; finite-element analysis; hole-patterning; instability problem; laser machining; lumped analytical model; material anisotropy; mechanical properties; minimally invasive medical procedures; pattern design parameter; precurved tubes; robotic manipulator; steerable needle; tissue rupture; torsional deformation; torsional rigidity; Analytical model; Finite element analysis; Manipulators; Medical robotics; Concentric-tube robot; dexterous manipulation; mechanism design; medical robots and systems; tube patterning;
Journal_Title :
Robotics, IEEE Transactions on
DOI :
10.1109/TRO.2015.2481283
