DocumentCode
70316
Title
Modeling and Experimental Characterization of Propulsion of a Spiral-Type Microrobot for Medical Use in Gastrointestinal Tract
Author
Hao Zhou ; Alici, Gursel ; Trung Duc Than ; Weihua Li
Author_Institution
Sch. of Mech., Mater. & Mechatron. Eng., Univ. of Wollongong, Wollongong, NSW, Australia
Volume
60
Issue
6
fYear
2013
fDate
Jun-13
Firstpage
1751
Lastpage
1759
Abstract
In this paper, a spiral-type medical robot based on an endoscopic capsule was propelled in a fluidic and tubular environment using electromagnetic actuation. Both modeling and experimental methods have been employed to characterize the propulsion of the robotic capsule. The experiments were performed not only in a simulated environment (vinyl tube filled with silicone oil) but also in a real small intestine. The effects of the spiral parameters including lead, spiral height, the number of spirals, and cross section of the spirals on the propulsion efficiency of the robot are investigated. Based on the transmission efficiency from rotation to translation as well as the balancing of the microrobot in operation, it is demonstrated that the robot with two spirals could provide the best propulsion performance when its lead is slightly smaller than the perimeter of the capsule. As for the spiral height, it is better to use a larger one as long as the intestine´s size allows. Based on the simulation and experimental results presented, this study quantifies the influence of the spiral structure on the capsule´s propulsion. It provides a helpful reference for the design and optimization of the traction topology of the microrobot navigating inside the mucus-filled small intestine.
Keywords
biological fluid dynamics; biological organs; computational fluid dynamics; electromagnetic actuators; endoscopes; medical robotics; microrobots; electromagnetic actuation; endoscopic capsule; fluidic environment; gastrointestinal tract; medical use; mucus-filled small intestine; real small intestine; robotic capsule propulsion; silicone oil filled vinyl tube; spiral height; spiral structure; spiral-type medical robot; spiral-type microrobot propulsion; traction topology; transmission efficiency; tubular environment; Fluids; Force; Propulsion; Robots; Shape; Spirals; Torque; Design optimization; magnetic propulsion; medical robotics; spiral-type microrobot; Animals; Capsule Endoscopes; Electromagnetic Phenomena; Equipment Design; Intestine, Small; Models, Biological; Mucus; Robotics; Swine; Viscosity;
fLanguage
English
Journal_Title
Biomedical Engineering, IEEE Transactions on
Publisher
ieee
ISSN
0018-9294
Type
jour
DOI
10.1109/TBME.2012.2228001
Filename
6355633
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