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Development of a propulsion system for a biomimetic thruster 被引量:2

Development of a propulsion system for a biomimetic thruster
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摘要 We studied theoretically and experimentally a biomimetic propulsion system inspired by the motility mechanisms of bacteria such as E. coli. Our goal was to investigate the effect of the "complex" filament of Rhizobium Meliloti bacteria on thrust force. The complex filament is a helically perturbed filament,similar to a plain filament threaded through a small helix. The propulsive performance of this system was estimated by modeling the dynamics of helical wave motion in viscous fluid. The model consists of a helical filament which is axially rotated at angular velocity ω. Resistive force theory(RFT) was applied to this model to calculate the thrust force and required torque. The Buckingham PI theorem(non-dimensional analysis) was also used to analyze the theoretical results. The procedure for making a complex filament with various pitch angles θs from a small helix and plain filament is explained in detail. To validate the theoretical results for helical wave propulsion and compare the characteristics of complex and plain filaments together,an experiment was performed to measure the thrust forces in silicone oil. The experimental results agreed with the theoretical values predicted by RFT. The thrust forces of complex filaments depended on the shape of small helix winding. The maximum thrust force was achieved at a small helix pitch angle of θs = 45°. In addition,we found that the thrust force generated by a complex filament had a value about 10% higher than that of a plain filament with the same equivalent diameter de. We studied theoretically and experimentally a biomimetic propulsion system inspired by the motility mechanisms of bacteria such as E. coli. Our goal was to investigate the effect of the "complex" filament of Rhizobium Meliloti bacteria on thrust force. The complex filament is a helically perturbed filament, similar to a plain filament threaded through a small helix. The propulsive per- formance of this system was estimated by modeling the dynamics of helical wave motion in viscous fluid. The model consists of a helical filament which is axially rotated at angular velocity co. Resistive force theory (RFT) was applied to this model to calculate the thrust force and required torque. The Buckingham PI theorem (non-dimensional analysis) was also used to analyze the theo- retical results. The procedure for making a complex filament with various pitch angles 0s from a small helix and plain filament is explained in detail. To validate the theoretical results for helical wave propulsion and compare the characteristics of complex and plain filaments together, an experiment was performed to measure the thrust forces in silicone oil. The experimental results agreed with the theoretical values predicted by RFT. The thrust forces of complex filaments depended on the shape of small helix wind- ing. The maximum thrust force was achieved at a small helix pitch angle of θ = 45°. In addition, we found that the thrust force generated by a complex filament had a value about 10% higher than that of a plain filament with the same equivalent diameter de.
出处 《Chinese Science Bulletin》 SCIE EI CAS 2011年第4期432-438,共7页
基金 supported by Konkuk University in 2010
关键词 推进系统 仿生 推进器 大肠杆菌 广播影视 螺旋波 旋转角速度 无量纲分析 biomimetic micro-robots, swimming micro-robots, propulsion of flagella, medical application
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  • 1Bogue R. The development of medical microrobots: A review of progress. J Ind Robot, 2008, 35:294-299.
  • 2Sitti M. Design methodology for biomimetic propulsion of miniature swimming robots. J Dyn Syst Meas Contr, 2006, 128:3643.
  • 3Wang Z, Hang G, Li J, et al. A micro robot fish with embedded SMA wire actuated flexible biomimetic fin. J Sens Actuators, 2008, 144: 354-360.
  • 4Kim B, Kim D H, Jung J, et al. A biomimetic undulatory tadpole robot using ionic polymer-metal composite actuators. Smart Mater Struct, 2005, 14:1579-1585.
  • 5Fukuda T, Kawamoto A, Arai F, et al. Steering mechanism of underwater micro mobile robot. In: Proc. IEEE Int Conf on Robo and Auto Nagoya, Japan, 21-27 May 1995. 363-368.
  • 6Zhang W, Guo S X, Asaka K J. A new type of hybrid fish-like microrobot. Int J Autom Comput, 2006, 3:358.
  • 7Nguyen Q S, Heo S, Park H C, et al. A fish robot driven by piezoceramic actuators and a miniaturized power supply. Int J Control Autom Syst, 2009, 7:267-272.
  • 8Kim M J, Bird J C, van Parys A J, et al. A macroscopic scale model of bacterial flagellar bundling. Proc Nat Acad Sci USA, 2003, 100:15481.
  • 9Chwang T, Wu T. A note on the helical movement of micro-organisms. Proc R Soc London Ser B, 1971, 178:327-346.
  • 10Jung S H, Mareck K, Fauci L, et al. Rotational dynamics of a superhelix towed in a stokes fluid. Phys Fluids, 2007, 19:103105.

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