대한기계학회논문집A (Transactions of the Korean Society of Mechanical Engineers A)

  • 제31권1호
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  • Pages.36-42
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  • 2007
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  • 1226-4873(pISSN)
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  • 2288-5226(eISSN)
대한기계학회 (The Korean Society of Mechanical Engineers)
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인공근육형 LIPCA를 이용한 물고기 모방 로봇의 설계, 제작 및 실험

Mechanical Design Fabrication and Test of a Biomimetic Fish Robot Using LIPCA as an Artificial Muscle

  • 허석 (건국대학교 인공근육연구센터) ;
  • 테디 위구나 (건국대학교 대학원 신기술융합학과) ;
  • 구남서 (건국대학교 대학원 신기술융합학과) ;
  • 박훈철 (건국대학교 신기술융합학과)
  • 발행 : 2007.01.01
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초록

This paper presents mechanical design, fabrication and test of a biomimetic fish robot actuated by a unimorph piezoceramic actuator, LIPCA(Lightweight Piezo-Composite curved Actuator.) We have designed a linkage mechanism that can convert bending motion of the LIPCA into the caudal fin movement. This linkage system consists of a rack-pinion system and four-bar linkage. Four types of artificial caudal fins that resemble caudal fin shapes of ostraciiform subcarangiform, carangiform, and thunniform fish, respectively, are attached to the posterior part of the robotic fish. The swimming test under 300 $V_{pp}$ input with 0.6 Hz to 1.2 Hz frequency was conducted to investigate effect of tail beat frequency and shape of caudal fin on the swimming speed of the robotic fish. At the frequency of 0.9 Hz, the maximum swimming speeds of 1.632 cm/s, 1.776 cm/s, 1.612 cm/s and 1.51 cm/s were reached for fish robots with ostraciiform, subcarangiform carangiform and thunniform caudal fins, respectively. The Strouhal number, which means the ratio between unsteady force and inertia force, or a measure of thrust efficiency, was calculated in order to examine thrust performance of the present biomimetic fish robot. The calculated Strouhal numbers show that the present robotic fish does not fall into the performance range of a fast swimming robot.

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참고문헌

  1. Sfakiotakis, M., Lane, D.M. and Davies, J.B.C., 1999, 'Review of Fish Swimming Modes for Aquatic Locomotion,' IEEE Journal of Oceanic Engineering, Vol. 24, pp. 237-252 https://doi.org/10.1109/48.757275
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  3. Barrett, D. S. et al, 1999, 'Drag Reduction in Fish-like Locomotion,' Journal of Fluid Mechanics, Vol. 392, pp. 183-212 https://doi.org/10.1017/S0022112099005455
  4. Anderson, J. M. and Kerrebrock, P. A. 1999, 'The Vorticity Control Unmanned Undersea Vehicle (VCUUV): An Autonomous Robot Tuna,' 11th International Symposium on Unmanned Untethered Submersible Technology, Durham
  5. Ayers, J., Wilbur, C. and Olcott, C. 2000, 'Lamprey Robots,' Proceeding of the International Symposium on Aqua Biomechanisms
  6. Guo, S. et. al, 1997, 'An Artificial Fish Robot using ICPF Actuator,' International Symposium on Micromechatronics and Human Science, Vol. 6, pp. 205-210
  7. Yoon, K. J. et al, 2004, 'Analytical Design Model for a Piezo-composite Unimorph Actuator and Its Verification using Lightweight Piezo-composite Curved Actuators,' Smart Materials and Structures, Vol. 13, pp. 459-467 https://doi.org/10.1088/0964-1726/13/3/002
  8. Myszka, D.H., 1999, Machines and Mechanisms- Applied Kinematics Analysis, Prentice-Hall
  9. Wiguna, T., Syaifuddin, M., Park, Hoon C. and Heo, S., 2006, 'Mechanical Design, Fabrication and Test of Biomimetic Fish Robot Using LIPCA as Artificial Muscle,' SPIE's International Conference on Smart structures and Materials, 6173-42, San Diego, USA

피인용 문헌

  1. Development of Biomimetic Underwater Vehicle using Single Actuator vol.33, pp.7, 2016, https://doi.org/10.7736/KSPE.2016.33.7.571
  2. Design and Control of a Biomimetic Fish Robot vol.36, pp.1, 2012, https://doi.org/10.3795/KSME-A.2012.36.1.001