Novel propelling mechanisms based on frictional interaction for endoscope robot

Y. T. Kim; D. E. Kim

Novel propelling mechanisms based on frictional interaction for endoscope robot

Y. T. Kim, D. E. Kim

Department of Mechanical Engineering

Research output: Contribution to specialist publication › Article

2 Citations (Scopus)

Abstract

In this work, two propelling mechanisms for a medical endoscope robotic system that can effectively move inside the intestinal track with minimum tissue damage were proposed. The first propelling mechanism utilized the rotational motion of a spiral-shaped body, and the second used the expansion and contraction motion of a stretchable body covered with polymeric surface structures. Both mechanisms were based on the frictional interaction between the robot body and the intestine surface. Through experiment, the biotribological behaviors of these mechanisms were investigated, and the major design parameters to achieve effective propelling motion with minimum tissue damage were identified. The results of this work will aid in the design of new endoscope robots that have motion control capability with adequate safety.

Original language	English
Pages	34-43
Number of pages	10
Volume	69
No.	2
Specialist publication	Tribology and Lubrication Technology
Publication status	Published - 2013 Feb

Bibliographical note

Funding Information:
This research has been supported by the Intelligent Mi-crosystem Center (IMC; http://www.microsystem.re.kr), which carries out one of the 21st century’s Frontier R&D Projects sponsored by the Korea Ministry of Commerce, Industry and Energy.

All Science Journal Classification (ASJC) codes

Mechanics of Materials
Mechanical Engineering
Surfaces and Interfaces
Surfaces, Coatings and Films

Cite this

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title = "Novel propelling mechanisms based on frictional interaction for endoscope robot",

abstract = "In this work, two propelling mechanisms for a medical endoscope robotic system that can effectively move inside the intestinal track with minimum tissue damage were proposed. The first propelling mechanism utilized the rotational motion of a spiral-shaped body, and the second used the expansion and contraction motion of a stretchable body covered with polymeric surface structures. Both mechanisms were based on the frictional interaction between the robot body and the intestine surface. Through experiment, the biotribological behaviors of these mechanisms were investigated, and the major design parameters to achieve effective propelling motion with minimum tissue damage were identified. The results of this work will aid in the design of new endoscope robots that have motion control capability with adequate safety.",

author = "Kim, {Y. T.} and Kim, {D. E.}",

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AB - In this work, two propelling mechanisms for a medical endoscope robotic system that can effectively move inside the intestinal track with minimum tissue damage were proposed. The first propelling mechanism utilized the rotational motion of a spiral-shaped body, and the second used the expansion and contraction motion of a stretchable body covered with polymeric surface structures. Both mechanisms were based on the frictional interaction between the robot body and the intestine surface. Through experiment, the biotribological behaviors of these mechanisms were investigated, and the major design parameters to achieve effective propelling motion with minimum tissue damage were identified. The results of this work will aid in the design of new endoscope robots that have motion control capability with adequate safety.

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Novel propelling mechanisms based on frictional interaction for endoscope robot

Abstract

Bibliographical note

All Science Journal Classification (ASJC) codes

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