Optimal Design and Numerical Simulation on Fish-Like Flexible Hydrofoil Propeller

Gang Xue; Yanjun Liu; Muqun Zhang; Wei Zhang; Jian Zhang; Huaqing Luo; Rui Jia

Otwarty dostęp

Optimal Design and Numerical Simulation on Fish-Like Flexible Hydrofoil Propeller

oraz

| 20 sty 2017

Polish Maritime Research

Tom 23 (2016): Zeszyt 4 (December 2016)

O artykule

Poprzedni artykuł

Następny artykuł

Zacytuj

Udostępnij

Data publikacji: 20 sty 2017

Zakres stron: 59 - 66

DOI: https://doi.org/10.1515/pomr-2016-0070

Słowa kluczowe
-bionics, flexible hydrofoil, phase angle, hydrodynamic coefficient

© 2017

This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 License.

1. Nagai, M. (2002). Thinking fluid dynamics with dolphins. US: IOS Press.Search in Google Scholar

2. Triantafyllou, M. S., and Triantafyllou, G. S. (1995). An efficient swimming machine. Scientific American, 272(3): 64-70.Search in Google Scholar

3. Koichi, H., Tadanori, T., and Kenkichi, T., 2000, “Study on turning performance of a fish robot,” First International Symposium on Aqua Bio-Mechanisms, pp. 287-292.Search in Google Scholar

4. Cheng, W., 2004, “Research on Simulation and Control Technology for Bionic Underwater Vehicle,” Ph.D. thesis, Harbin Engineering University, Harbin, China.Search in Google Scholar

5. Du, R. X., Li, Z., Kamal, Y. T., Pablo, V. A., 2015, “Robot Fish,” New York: Springer Tracts in Mechanical Engineering.10.1007/978-3-662-46870-8Search in Google Scholar

6. Liang, J. H., Zhang, W. F., Wen, L., Wang, T. M., Liu, and Y. J. (2010). Propulsion and Maneuvering Performances of Two-Joint Biorobotic Autonomous Underwater Behicle SPC-III. Robot, 32(6):726-731.Search in Google Scholar

7. Lighthill, M. J. (1960), Note on the swimming of slender fish, Journal of Fluid Mechanics, Vol.9: 305-317.Search in Google Scholar

8. Leroyer, A., Visonneau, M.(2005), Numerical methods for RANSE simulations of a self-propelled fish-like body, Journal of Fluids and Structures, Vol.20, No.7: 975-991.Search in Google Scholar

9. Zhao, Y., Wang G. Y., Huang, B., Wu, Q., Wang, F. F. (2015), Lagrangian-Based Investigation of Unsteady Vertex Structure Near Trailing Edge of a Hydrofoil, Transactions of Beijing Institute of Technology, Vol.35, No.7: 666-670.Search in Google Scholar

10. Romaneko, E. V. (2002). Fish and dolphin swimming. Bulgaria: Pensoft Publishers.Search in Google Scholar

11. Wang, L., Yu, J. Z., Hu, Y. H., Fan, R. F., Huo, J. Y., and Xie, G. M. (2006). Mechanism design and motion control of robotic dolphin. Acta Scientiarum Naturalium Universitatis Pekinensis, 42(3): 294-301.Search in Google Scholar

12. Wang, W. J. (2006). Optimal design of planar linkage based on Matlab optimization toolbox. Light Industry Machinery, 24(4): 76Search in Google Scholar

eISSN:: 2083-7429
Język:: Angielski

Częstotliwość wydawania:: 4 razy w roku
Dziedziny czasopisma:: Engineering, Introductions and Overviews, other, Geosciences, Atmospheric Science and Climatology, Life Sciences

Kanał RSS czasopisma

Optimal Design and Numerical Simulation on Fish-Like Flexible Hydrofoil Propeller

Data publikacji: 20 sty 2017

Zakres stron: 59 - 66

DOI: https://doi.org/10.1515/pomr-2016-0070

Słowa kluczowe-bionics, flexible hydrofoil, phase angle, hydrodynamic coefficient

© 2017

This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 License.

Słowa kluczowe
-bionics, flexible hydrofoil, phase angle, hydrodynamic coefficient