Design improvements and flap deflection evaluations with considering centrifugal load on active trailing edge flap

Visconti, Umberto; Eun, WonJong; Sim, JiSoo; Lee, Sang‐Woo; Shin, Su-Jung

doi:10.1108/aeat-10-2016-0165

Cited by 4 publications

(4 citation statements)

References 10 publications

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“…Equation 1 represents the characteristic equation in terms of applied voltage, stroke, and blocked force [33]. This equation is used to determine the ideal stroke by using the estimated force magnitude from the numerical analysis.…”

Section: Flap Skin Design and Actuator Selectionmentioning

confidence: 99%

Development and Testing of an Active Trailing Edge Morphing Demonstrator for a Rotary Wing

Zahoor

Sodja

Breuker

et al. 2021

ASME 2021 Conference on Smart Materials, Adaptive Structures and Intelligent Systems

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This paper discusses the development and whirl tower testing of an active translation induced camber morphing system for rotorcraft. The system deploys the morphing flap based on the amplitude and type of the input signal. As a case study, a demonstrator is developed and tested primarily under the centrifugal force generated by a whirl tower setup. The actuation system consists of amplified piezoelectric actuators, while the morphing skin is made out of carbon fiber prepreg composite material. The response of the morphing skin and the actuators is measured and compared to the numerical studies used to design the morphing demonstrator. Results indicate that the response of the active system, including the actuators and the flexible skin, matches well to those predicted during the numerical studies. The outcome of these studies shows that the system has the potential to be used for the primary control of the rotorcraft if operated at 1/revolution or for mitigating noise and vibration if operated at 2/revolution or higher frequencies. Subsequently, the concept can be integrated into a Mach-scaled rotor blade which can be tested under both aerodynamic and centrifugal loads to further assess its performance.

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Section: Flap Skin Design and Actuator Selectionmentioning

confidence: 99%

Development and Testing of an Active Trailing Edge Morphing Demonstrator for a Rotary Wing

Zahoor

Sodja

Breuker

et al. 2021

ASME 2021 Conference on Smart Materials, Adaptive Structures and Intelligent Systems

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“…An asymptotically exact cross-sectional analysis is performed using VABS and PreVABS. The cross-sectional design optimization framework used in this study was initially developed in previous studies [27][28][29]. The spar structure is modified to readily incorporate the flap drive shaft bearing in the prototype blade.…”

Section: Mach-scale Seoul National University Flap Rotor Analysismentioning

confidence: 99%

Investigation of Linear Higher Harmonic Control Algorithm for Rotorcraft Vibration Reduction

Lee

Kee

et al. 2020

Journal of Dynamic Systems, Measurement, and Control

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A linear quadratic Gaussian controller for active vibratory loads reduction in helicopters is proposed based on a revisited higher harmonic control input by active trailing-edge flaps. Conventional individual blade control input is redefined using N-1/rev inter-blade phase lead, N/rev collective, and N+1/rev inter-blade phase lag signals where 1/rev frequency modulation originate from the multi-blade coordinate transform. A Mach-scaled flap blade is designed and analyzed by the multi-body dynamics analysis DYMORE. A linear time-invariant representation is identified from N/rev envelopes of the input and output responses obtained by DYMORE analysis. A MATLAB/Simulink closed-loop control simulation is designed using the identified state-space realization. The N/rev vibratory loads are reduced up to 52% with flap deflections and the linear control results match well with the nonlinear responses obtained from DYMORE. Furthermore, the multi-variable closed-loop stability estimated by the loop transfer functions using disk margin analysis reveals sufficient gain and phase margins.

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“…In contrast to passive techniques, active control methods, including circulation control [48] and plasma actuators [49], outperform passive methods. In the aerospace industry, flaps are frequently utilized within lifting mechanisms due to their straightforward design, durability, and high efficiency [50,51]. A fully deformable flapping foil increased the power output by 2% compared to a traditional airfoil [52].…”

Section: Introductionmentioning

confidence: 99%

Numerically Investigating the Energy-Harvesting Performance of an Oscillating Flat Plate with Leading and Trailing Flaps

Saleh,

Sohn

2024

Energies

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This study investigates the power generation capability of an oscillating wing energy harvester equipped with two actively controlled flaps positioned at the leading and trailing flaps of the wing. Various parameters, including flap lengths and pitch angles for the leading flap and trailing flap, are explored through numerical simulations. The length of the main wing body ranges from 40% to 65% of the chord length, c, while the leading and trailing flaps vary accordingly, summing up to the total length of the flat plate c = 100%. The pitch angles of the two flaps are adjusted within predefined limits. The pitch angle for the leading flap varies between 25° and 55°, while the trailing flap’s angle ranges from 10° to 40° across 298 different simulation scenarios. The results indicate that employing both leading and trailing flaps enhances the power output compared to a wing with a single flap configuration. The trailing flap deflects the incoming fluid more vertically, while the leading flap increases pressure difference across the surface of the main wing body, synergistically improving overall performance. The power output occurs at a specific length percentage: a leading flap of 30%, a main wing body of 50%, and a trailing flap of 20%, with pitch angles of 50°, 85°, and 30°, respectively, increasing the output power increments by 4.39% compared to a wing with a leading flap, 4.92% compared to a wing with a trailing flap, and 28.24% compared to a single flat plate. The highest efficiency for the specified length percentages is 40.37%.

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Design improvements and flap deflection evaluations with considering centrifugal load on active trailing edge flap

Cited by 4 publications

References 10 publications

Development and Testing of an Active Trailing Edge Morphing Demonstrator for a Rotary Wing

Development and Testing of an Active Trailing Edge Morphing Demonstrator for a Rotary Wing

Investigation of Linear Higher Harmonic Control Algorithm for Rotorcraft Vibration Reduction

Numerically Investigating the Energy-Harvesting Performance of an Oscillating Flat Plate with Leading and Trailing Flaps

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