The Dynamics of Passive Wing-Pitching in Hovering Flight of Flapping Micro Air Vehicles Using Three-Dimensional Aerodynamic Simulations

Chang, Longlong; Pérez-Arancibia, Néstor O.

doi:10.2514/6.2016-0013

Cited by 9 publications

(2 citation statements)

References 28 publications

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“…To demonstrate the suitability of the sensing system for measuring signals in the millinewton range with micronewton resolution, we compare the experimental average vertical forces generated by the flapping-wing microrobot shown in figure 9(a) with CFD simulations for flapping frequencies in the range [ ] 60 : 100 Hz. In this way, we demonstrate that the proposed fabrication method will enable the continuation and extension of the research in [46] which uses a quasi-steady model to compare and validate the mN-scale measured instantaneous vertical forces generated by a cm-scale passively-pitching flapping wing, and the works in [47][48][49] which present CFD-based studies of the same type of microforce generation mechanism. For the performance of the experiments, we employ the setup already shown in figure 6(a).…”

Section: Experimental Examplementioning

confidence: 88%

“…During periodic flapping, these mechanisms generate lift forces dependent on its pitching profile. Here, we applied the method in [47] to numerically solve a simplified dynamics model of the robot, which is based on the Navier-Stokes equations that describe the fluidstructure interaction problem of the wings interacting with the surrounding air for each frequency of interest.…”

Section: Experimental Examplementioning

confidence: 99%

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Clip-brazing for the design and fabrication of micronewton-resolution millimeter-scale force sensors

Singer¹,

Chang²,

Calderón³

et al. 2019

Smart Mater. Struct.

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We present clip-brazing as a new method to construct millimeter-to-centimeter-scale metal structures with micron-scale precision that is fast, scalable and extremely low-cost. Small structures with demanding requirements on both dimensional tolerances and dynamic force responses to time-varying loads are difficult to fabricate and expensive to iteratively prototype. The technique introduced here enables precise placement of strong metallic brazed bonds to create 3D structures with micrometric accuracy, which in this work is exemplified through the design and construction of a broadband micronewton-resolution force-sensing device. The fabrication method uses tensioned clips made from a silver brazing alloy wire to accurately place and control the volume of the metal that joins and supports the pieces that compose the microstructures. The use of clips also allows the simultaneous fusion of all the connections in the structure during a single heating sequence, reducing tolerance stack-up. To analyze the quality and strength of the brazes, we employed scanning electron microscopy (SEM) on cross-sections and tensile testing on dogbone-shaped sample pieces, respectively. After proper calibration, the functionality of the constructed micro-force-sensing system was analyzed and demonstrated using constant a priori known weights and the vertical periodic forces produced by an 83 mg flapping-wing microrobot (including a 3 mg attachment truss). The static tests, in combination with solid-mechanics analyses and simulations based on finite-element analysis (FEA), provide compelling evidence of the high accuracy and precision of the force sensing system for frequencies below 167.5 Hz. Furthermore, the shape characteristics and average values of the measured periodic signals are compared to computational fluid dynamics (CFD) simulations and validated for two sets of flapping angles across the frequency range from 55 to 100 Hz. These results validate the proposed approach as a viable tool for microrobotic design and fabrication.

show abstract

Section: Experimental Examplementioning

confidence: 88%

Section: Experimental Examplementioning

confidence: 99%

Clip-brazing for the design and fabrication of micronewton-resolution millimeter-scale force sensors

Singer¹,

Chang²,

Calderón³

et al. 2019

Smart Mater. Struct.

View full text Add to dashboard Cite

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A Multiplatform Position Control Scheme for Flying Robotic Insects

Bena

Nguyen

Yang

et al. 2022

J Intell Robot Syst

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Control of Flying Robotic Insects: A Perspective and Unifying Approach

Calderón

Chen

Yang

et al. 2019

2019 19th International Conference on Advanced Robotics (ICAR)

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We discuss the problem of designing and implementing controllers for insect-scale flapping-wing micro air vehicles (FWMAVs), from a unifying perspective and employing two different experimental platforms; namely, a Harvard RoboBee-like two-winged robot and the four-winged USC Bee + . Through experiments, we demonstrate that a method that employs quaternion coordinates for attitude control, developed to control quadrotors, can be applied to drive both robotic insects considered in this work. The proposed notion that a generic strategy can be used to control several types of artificial insects with some common characteristics was preliminarily tested and validated using a set of experiments, which include position-and attitude-controlled flights. We believe that the presented results are interesting and valuable from both the research and educational perspectives.

show abstract

The Dynamics of Passive Wing-Pitching in Hovering Flight of Flapping Micro Air Vehicles Using Three-Dimensional Aerodynamic Simulations

Cited by 9 publications

References 28 publications

Clip-brazing for the design and fabrication of micronewton-resolution millimeter-scale force sensors

Clip-brazing for the design and fabrication of micronewton-resolution millimeter-scale force sensors

A Multiplatform Position Control Scheme for Flying Robotic Insects

Control of Flying Robotic Insects: A Perspective and Unifying Approach

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