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Elastic storage enables robustness of flapping wing dynamics

Xuefei Cai, Yujing Xue, Dmitry Kolomenskiy, Ru Xu, Hao Liu

2022Bioinspiration & Biomimetics13 citationsDOI

Abstract

Flying insects could perform robust flapping-wing dynamics under various environments while minimizing the high energetic cost by using elastic flight muscles and motors. Here we propose a fluid-structure interaction model that couples unsteady flapping aerodynamics and three-torsional-spring-based elastic wing-hinge dynamics to determine passive and active mechanisms (PAM) in bumblebee hovering. The results show that a strategy of active-controlled stroke, passive-controlled wing pitch and deviation enables an optimal elastic storage. The flapping-wing dynamics is robust, which is characterized by dynamics-based passive elevation-rotation and aerodynamics-based passive feathering-rotation, capable of producing aerodynamic force while achieving high power efficiency over a broad range of wing-hinge stiffness. A force-impulse model further confirms the capability of external perturbation robustness under the PAM-based strategy.

Topics & Concepts

FlappingWingAerodynamicsHingeRobustness (evolution)ActuatorControl theory (sociology)Aerodynamic forceImpulse (physics)Wing twistStiffnessEngineeringStructural engineeringMechanicsAerospace engineeringComputer sciencePhysicsAngle of attackClassical mechanicsBiochemistryControl (management)ChemistryElectrical engineeringArtificial intelligenceGeneBiomimetic flight and propulsion mechanismsPhysiological and biochemical adaptationsFish Ecology and Management Studies
Elastic storage enables robustness of flapping wing dynamics | Litcius