A simulation-based study on longitudinal gust response of flexible flapping wings

Winged animals such as insects are capable of flying and surviving in an unsteady and unpredictable aerial environment. They generate and control aerodynamic forces by flapping their flexible wings. While the dynamic shape changes of their flapping wings are known to enhance the efficiency of their flight, they can also affect the stability of a flapping wing flyer under unpredictable disturbances by responding to the sudden changes of aerodynamic forces on the wing. In order to test the hypothesis, the gust response of flexible flapping wings is investigated numerically with a specific focus on the passive maintenance of aerodynamic forces by the wing flexibility. The computational model is based on a dynamic flight simulator that can incorporate the realistic morphology, the kinematics, the structural dynamics, the aerodynamics and the fluid–structure interactions of a hovering hawkmoth. The longitudinal gusts are imposed against the tethered model of a hovering hawkmoth with flexible flapping wings. It is found that the aerodynamic forces on the flapping wings are affected by the gust, because of the increase or decrease in relative wingtip velocity or kinematic angle of attack. The passive shape change of flexible wings can, however, reduce the changes in the magnitude and direction of aerodynamic forces by the gusts from various directions, except for the downward gust. Such adaptive response of the flexible structure to stabilise the attitude can be classified into the mechanical feedback, which works passively with minimal delay, and is of great importance to the design of bio-inspired flapping wings for micro-air vehicles.

[1]  S. M. Walker,et al.  Smart wing rotation and trailing-edge vortices enable high frequency mosquito flight , 2017, Nature.

[2]  John Young,et al.  Details of Insect Wing Design and Deformation Enhance Aerodynamic Function and Flight Efficiency , 2009, Science.

[3]  R. Mittal,et al.  Time-Varying Wing-Twist Improves Aerodynamic Efficiency of Forward Flight in Butterflies , 2013, PloS one.

[4]  T. Q. Le,et al.  Improvement of the aerodynamic performance by wing flexibility and elytra–hind wing interaction of a beetle during forward flight , 2013, Journal of The Royal Society Interface.

[5]  H. Park,et al.  Relationship between wingbeat frequency and resonant frequency of the wing in insects , 2013, Bioinspiration & biomimetics.

[6]  M. Dickinson,et al.  The control of flight force by a flapping wing: lift and drag production. , 2001, The Journal of experimental biology.

[7]  Danesh K. Tafti,et al.  Effect of Frontal Gusts on Forward Flapping Flight , 2010 .

[8]  Andrew M. Mountcastle,et al.  Wing flexibility improves bumblebee flight stability , 2016, Journal of Experimental Biology.

[9]  Mao Sun,et al.  Dynamic flight stability of a hovering bumblebee , 2005, Journal of Experimental Biology.

[10]  Michael H Dickinson,et al.  The influence of sensory delay on the yaw dynamics of a flapping insect , 2012, Journal of The Royal Society Interface.

[11]  Adrian L. R. Thomas,et al.  Leading-edge vortices in insect flight , 1996, Nature.

[12]  R. Wootton Support and deformability in insect wings , 2009 .

[13]  Adrian L. R. Thomas,et al.  Automatic aeroelastic devices in the wings of a steppe eagle Aquila nipalensis , 2007, Journal of Experimental Biology.

[14]  Hao Liu,et al.  Integrated modeling of insect flight: From morphology, kinematics to aerodynamics , 2009, J. Comput. Phys..

[15]  M. Dickinson,et al.  Wing rotation and the aerodynamic basis of insect flight. , 1999, Science.

[16]  Toshiyuki Nakata,et al.  A fluid-structure interaction model of insect flight with flexible wings , 2012, J. Comput. Phys..

[17]  Mao Sun,et al.  Effects of wing deformation on aerodynamic forces in hovering hoverflies , 2010, Journal of Experimental Biology.

[18]  Mao Sun,et al.  Insect flight dynamics: Stability and control , 2014 .

[19]  Hiroto Tanaka,et al.  Biomechanics and biomimetics in insect-inspired flight systems , 2016, Philosophical Transactions of the Royal Society B: Biological Sciences.

[20]  S. Combes,et al.  Rolling with the flow: bumblebees flying in unsteady wakes , 2013, Journal of Experimental Biology.

[21]  W. H. Melbourne,et al.  Atmospheric winds and their implications for microair vehicles , 2006 .

[22]  Toshiyuki Nakata,et al.  Aerodynamic performance of a hovering hawkmoth with flexible wings: a computational approach , 2012, Proceedings of the Royal Society B: Biological Sciences.

[23]  Jen-San Chen,et al.  On the natural frequencies and mode shapes of dragonfly wings , 2008 .

[24]  R. Mittal,et al.  Hawkmoth flight performance in tornado-like whirlwind vortices , 2014, Bioinspiration & biomimetics.

[25]  A. Biewener,et al.  Hummingbird flight stability and control in freestream turbulent winds , 2015, The Journal of Experimental Biology.

[26]  R. B. Srygley,et al.  Unconventional lift-generating mechanisms in free-flying butterflies , 2002, Nature.

[27]  Rajat Mittal,et al.  Hawkmoth flight stability in turbulent vortex streets , 2013, Journal of Experimental Biology.

[28]  R. Dudley,et al.  Into turbulent air: size-dependent effects of von Kármán vortex streets on hummingbird flight kinematics and energetics , 2014, Proceedings of the Royal Society B: Biological Sciences.

[29]  T. Daniel,et al.  Into thin air: contributions of aerodynamic and inertial-elastic forces to wing bending in the hawkmoth Manduca sexta , 2003, Journal of Experimental Biology.

[30]  R. Murray,et al.  Flying Drosophila stabilize their vision-based velocity controller by sensing wind with their antennae , 2014, Proceedings of the National Academy of Sciences.

[31]  J S Humbert,et al.  Kinematic strategies for mitigating gust perturbations in insects , 2013, Bioinspiration & biomimetics.

[32]  S. Combes,et al.  Turbulence-driven instabilities limit insect flight performance , 2009, Proceedings of the National Academy of Sciences.

[33]  R J Full,et al.  How animals move: an integrative view. , 2000, Science.

[34]  R. Full,et al.  The role of the mechanical system in control: a hypothesis of self-stabilization in hexapedal runners , 1999 .

[35]  F. Lehmann,et al.  Bumblebee Flight in Heavy Turbulence. , 2015, Physical review letters.

[36]  Hao Liu,et al.  Bumblebees minimize control challenges by combining active and passive modes in unsteady winds , 2016, Scientific Reports.

[37]  Adrian L. R. Thomas,et al.  Animal flight dynamics II. Longitudinal stability in flapping flight. , 2002, Journal of theoretical biology.

[38]  C. Ellington,et al.  The mechanics of flight in the hawkmoth Manduca sexta. I. Kinematics of hovering and forward flight. , 1997, The Journal of experimental biology.