[1] Yin Dongfu, Zhang Zhisheng,. Aerodynamics of flexible wing in bees’ hovering flight [J]. Journal of Southeast University (English Edition), 2013, 29 (4): 419-424. [doi:10.3969/j.issn.1003-7985.2013.04.012]
Copy
Aerodynamics of flexible wing in bees’ hovering flight(
)
)Journal of Southeast University (English Edition)[ISSN:1003-7985/CN:32-1325/N]
- Volumn:
- 29
- Issue:
- 2013 4
- Page:
- 419-424
- Research Field:
- Other Disciplines
- Publishing date:
- 2013-12-20
Info
- Title:
- Aerodynamics of flexible wing in bees’ hovering flight
- Author(s):
- Yin Dongfu; Zhang Zhisheng
- School of Mechanical Engineering, Southeast University, Nanjing 211189, China
- Keywords:
- flapping wing; coordinate systems; hovering flight; computational fluid dynamics; aerodynamics force; power
- PACS:
- V211.3
- DOI:
- 10.3969/j.issn.1003-7985.2013.04.012
- Abstract:
- The aerodynamics of 2-dimensional flexible wings in bees’ normal hovering flight is studied. Four insect flapping flight coordinate systems, including a global system, a body-fixed system, a rigid wing-fixed system and a flexible wing-fixed system, are established to represent the insects’ position, gesture, wing movement and wing deformation, respectively. Then the transformations among four coordinate systems are studied. It is found that the elliptic coordinate system can improve the computation accuracy and reduce the calculation complexity in a 2-dimensional rigid wing. The computation model of a 2-dimensional flexible wing is established, and the changes of the force, moment, and power are investigated. According to the computation results, the large lift and drag peaks at the beginning and end of the stroke can be explained by the superposition of the rapid translational acceleration, the fast pitching-up rotation and the Magnus effect; and the small force and drag peaks can be explained by the convex flow effect and the concave flow effect. Compared with the pressure force, pressure moment and translational power, the viscous force, viscous moment and rotational power are small and can be ignored.
References:
[1] Ellington C P. The aerodynamics of hovering insect flight. VI. lift and power requirements[J]. Philosophical Transactions of the Royal Society of London Series B—Biological Sciences, 1984, 305(1122):145-181.
[2] Sun Mao, Tang Jian. Lift and power requirements of hovering flight in Drosophila virilis[J]. The Journal of Experimental Biology, 2002, 205(16): 2413-2427.
[3] Wang Z J, Birch J M, Dickinson M H. Unsteady forces and flows in low Reynolds number hovering flight: two-dimensional computations vs robotic wing experiments[J]. The Journal of Experimental Biology, 2004, 207(3):449-460.
[4] Liu Hao. Integrated modeling of insect flight: from morphology, kinematics to aerodynamics[J]. Journal of Computational Physics, 2009, 228(2): 439-459.
[5] Mountcastle A M, Combes S A. Wing flexibility enhances load-lifting capacity in bumblebees[J]. Proceedings of the Royal Society of Series B—Biological Sciences, 2013, 280(22): 1-8.
[6] Tian Fangbo, Luo Haoxiang, Song Jialei, et al. Force production and asymmetric deformation of a flexible flapping wing in forward flight[J]. Journal of Fluids and Structures, 2013, 36:149-161.
[7] Tanaka H, Whitney J P, Wood R J. Effect of flexural and torsional wing flexibility on lift generation in hoverfly flight[J]. Integrative and Comparative Biology, 2011, 51(1): 142-150.
[8] Fry S N, Sayaman R, Dickinson M H. The aerodynamics of hovering flight in Drosophila[J]. The Journal of Experimental Biology, 2005, 208(12):2303-2318.
[9] Wang Z J. Two dimensional mechanism for insect hovering[J]. Physical Review Letters, 2000, 85(10): 2216-2219.
[10] Wang Z J. The role of drag in insect hovering[J]. The Journal of Experimental Biology, 2004, 207(23):4147-4155.
[11] Sun Mao. High-lift generation and power requirements of insect flight[J]. Fluid Dynamics Research, 2005, 37(1/2):21-39.
[12] Wang Z J. Computation of insect hovering[J]. Mathematical Methods in the Applied Sciences, 2001, 24(17/18):1515-1521.
[13] Lu Guang, Yan Jingping, Zhang Zhisheng, et al. Dissection of a flexible wing’s performance for insect-inspired flapping-wing micro air vehicles[J]. Advanced Robotics, 2012, 26(5/6): 409-435.
[14] Dickinson M H, Lehmann F O, Sane S. Wing rotation and the aerodynamic basis of insect flight[J]. Science, 1999, 284(5422):1954-1960.
[15] Zhang Genbao, Liu Yijun, Shi Wu, et al. Numerical simulation of two-dimensional flapping-wing MAVs[J]. Journal of Donghua University: Natural Science, 2011, 37(2): 256-260.(in Chinese)
Memo
- Memo:
-
Biographies: Yin Dongfu(1986—), male, graduate; Zhang Zhisheng(corresponding author), male, doctor, professor, oldbc@seu.edu.cn.
Foundation items: The Fundamental Research Funds for the Central Universities(No.3202003905), Scientific Innovation Research of College Graduates in Jiangsu Province(No.CXLX12_0080).
Citation: Yin Dongfu, Zhang Zhisheng.Aerodynamics of flexible wing in bees’ hovering flight[J].Journal of Southeast University(English Edition), 2013, 29(4):419-424.[doi:10.3969/j.issn.1003-7985.2013.04.012]