Realisation and testing of novel fully articulated bird-inspired flapping wings for efficient and agile UAVs

Kumar, David; Goyal, Tigmanshu; Kamle, Sudhir; Mohite, P.M.; Lau, Edwin M.

doi:10.1017/aer.2021.55

Cited by 5 publications

(3 citation statements)

References 42 publications

(65 reference statements)

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“…Meanwhile, in [70], a mechanism was developed that can actively implement and control flapping, flexing, and twisting by using servo motors. This FWAV is to be used in wind tunnel tests to analyze aerodynamic characteristics according to various parameters.…”

Section: Multi-axis Flapping Mechanismmentioning

confidence: 99%

“…Rigid mechanism [61][62][63][64][65]75,76] Compliant mechanism [57,77] Active Rigid mechanism [5,70,78] Compliant mechanism [66] Wrist flexing…”

Section: Passivementioning

confidence: 99%

“…Rigid mechanism [5,[78][79][80][81][82][83] Compliant mechanism [67,68] Active Rigid mechanism [70] Compliant mechanism -* passive: Different motions occur simultaneously while flapping without increasing the degree of freedom. ** active: As the degree of freedom increases, an additional actuator is required, and individual control is possible.…”

Section: Passivementioning

confidence: 99%

See 2 more Smart Citations

A Review of Flapping Mechanisms for Avian-Inspired Flapping-Wing Air Vehicles

Han

Yang

et al. 2023

Aerospace

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This study focuses on the flapping mechanisms found in recently developed biometric flapping-wing air vehicles (FWAVs). FWAVs mimic the flight characteristics of flying animals, providing advantages such as maneuverability, inconspicuousness, and excellent flight efficiency in the low Reynolds number region. The flapping mechanism is a critical part of determining the aerodynamic performance of an FWAV since it is directly related to the wing motion. In this study, the flight characteristics of birds and bats are introduced, the incorporation of these flight characteristics into the development of FWAVs is elucidated, and the utilization of these flight characteristics in the development of FWAVs is explained. Next, the classification and analysis of flapping mechanisms are conducted based on wing motion and the strategy for improving aerodynamic performance. Lastly, the current research gap is elucidated, and potential future directions for further research are proposed. This review can serve as a guide during the early development stage of FWAVs.

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Section: Multi-axis Flapping Mechanismmentioning

confidence: 99%

“…Rigid mechanism [61][62][63][64][65]75,76] Compliant mechanism [57,77] Active Rigid mechanism [5,70,78] Compliant mechanism [66] Wrist flexing…”

Section: Passivementioning

confidence: 99%

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A Review of Flapping Mechanisms for Avian-Inspired Flapping-Wing Air Vehicles

Han

Yang

et al. 2023

Aerospace

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A review of bird-like flapping wing with high aspect ratio

Xie

Gao

Meng

et al. 2023

Chinese Journal of Aeronautics

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Role of flexibility on the aerodynamic performance of a resonating hummingbird-inspired wing

Kumar

Singh²,

Mohite³

et al. 2022

Aeronaut. j.

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This work investigates the role of flexibility and resonant excitation on the deformation mechanism and aerodynamic performance of flapping wings. A hummingbird-inspired wing (HIW) is considered and designed to have a bone-like stiffener made of carbon fibre/epoxy (CF/E) composite attached to a membrane made of carbon nanotubes/polypropylene (CNTs/PP) nanocomposite representing the flexible part of the natural wing. The designed HIW model is analysed through fluid-structure interaction simulations performed at frequencies near and at resonant frequency. It is found that HIW generates desired bending and twisting deformations that are coupled. These deformation mechanisms are studied in detail with the help of time-varying deflections and bending-twisting angles. Further, the simultaneous effect of these parameters on the aerodynamic performance of the wing is also investigated. It is observed that the coupled nature of bending and twisting deformations is critical in enhancing the aerodynamic performance of flapping wings. In addition to that, the resonance generates higher amplitude of desired structural deformations that further enhances thrust as well as lift generation capability of the wing. The underlying mechanism for this is also explained by studying the flow around the deflected surface of the wing. Compared to off-resonant frequencies, vorticity and pressures are substantially higher for the wing at resonance. A physical model of HIW is realised using CNTs/PP and CF/E composites to perform experimental wing motion analysis and to validate the computational results. In conclusion, the present study provides a basis to design efficient biomimetic flapping wings for micro aerial vehicles (MAVs) by exploring flexibility and resonant excitation.

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Realisation and testing of novel fully articulated bird-inspired flapping wings for efficient and agile UAVs

Cited by 5 publications

References 42 publications

A Review of Flapping Mechanisms for Avian-Inspired Flapping-Wing Air Vehicles

A Review of Flapping Mechanisms for Avian-Inspired Flapping-Wing Air Vehicles

A review of bird-like flapping wing with high aspect ratio

Role of flexibility on the aerodynamic performance of a resonating hummingbird-inspired wing

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