Optimized design of real-scale A320 morphing high-lift flap with shape memory alloys and innovative skin

Jodin, Gurvan; Tekap, Yannick Bmegaptche; Saucray, J M; Rouchon, Jean-François; Triantafyllou, Michael S.; Braza, Marianna

doi:10.1088/1361-665x/aae2ef

Cited by 24 publications

(16 citation statements)

References 21 publications

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“…Our numerical study focuses on the morphing by means of MFC (piezoactuators) near the trailing edge region at low-amplitudes with higher frequencies, applied to a twoelement A320 airfoil/flap configuration having a chord of 2.40 m and a flap's chord of 1 m at the take-off position and Reynolds number of 2.25x10 6 . This corresponds to a near scale 1 configuration of the A320's flap, in the context of the so-called Large Scale (LS) prototype of the European research programme SMS, for which the camber control has been designed experimentally by Jodin et al (2018) The present numerical study first focuses on the investigation of the morphing effects in the clean configuration of the LS prototype, providing also a validation of the numerical results for this configuration and secondly, the investigation of the morphing effects in the case of the two-element at the take-off configuration (airfoil-gap-flap). The flow dynamics around the A320 airfoil-gap-flap is analysed in detail concerning the static and morphing cases.…”

Section: Cmentioning

confidence: 99%

“…Our numerical study focuses on the morphing by means of MFC (piezoactuators) near the trailing edge region at low-amplitudes with higher frequencies, applied to a two-element A320 airfoil/flap configuration having a chord of 2.40 m and a flap’s chord of 1 m at the take-off position and Reynolds number of 2.25 × 10 6 . This corresponds to a near scale 1 configuration of the A320’s flap, in the context of the so-called large scale (LS) prototype of the European research programme SMS, for which the camber control has been designed experimentally by Jodin et al (2018).…”

Section: Introductionmentioning

confidence: 99%

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Numerical investigation of frequency-amplitude effects of dynamic morphing for a high-lift configuration at high Reynolds number

Marouf

Tekap

Simiriotis

et al. 2020

HFF

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Purpose The purpose of this study illustrates the morphing effects around a large-scale high-lift configuration of the Airbus A320 with two elements airfoil-flap in the take-off position. The flow around the airfoil-flap and the near wake are analysed in the static case and under time-dependent vibration of the flap trailing-edge known as the dynamic morphing. Design/methodology/approach Experimental results obtained in the subsonic wind tunnel S1 of Institut de Mécanique des Fluides de Toulouse of a single wing are discussed with high-fidelity numerical results obtained by using the Navier–Stokes multi-block (NSMB) code with advanced turbulent modelling able to capture the predominant instabilities and coherent structure dynamics. An explanation of the dynamic time-dependent grid deformation is provided, which is used in the NSMB code to simulate the flap’s trailing-edge deformation in the morphing configuration. Finally, power spectral density is performed to reveal the coherent wake structures and their modification because of the morphing. Findings Frequency of vibration and amplitude of deformation effects are investigated for different morphing cases. Optimal morphing regions at a specific frequency and a slight deformation were able to attenuate the predominant natural shear-layer frequency and to considerably decrease the width of the von Kármán vortices with a simultaneous increase of aerodynamic performances. Originality/value The new concept of future morphed wings is proposed for a large scale A320 prototype at the take-off position. The dynamic morphing of the flap’s trailing-edge is simulated for the first time for high-lift two-element configuration. In addition, the wake analysis performed helped to show the turbulent structures according to the organised eddy simulation model.

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Section: Cmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Numerical investigation of frequency-amplitude effects of dynamic morphing for a high-lift configuration at high Reynolds number

Marouf

Tekap

Simiriotis

et al. 2020

HFF

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“…The hybrid composite actuator could maintain a deformed state without additional current for heating by using the shape memory effects of SMP. Jodin et al [22] provided an accurate scale flap of a civil aircraft, which could carry realistic aerodynamic loading of several tons with SMA as the macro-actuators. In Leal et al's study, the SMA wires were embedded into an elastic matrix and wound through each pin in turn.…”

Section: Introductionmentioning

confidence: 99%

Design of a Morphing Skin with Shape Memory Alloy Based on Equivalent Thermal Stress Approach

Zhang

Gao

et al. 2022

Micromachines

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Shape memory alloy (SMA) is one of the potential driving devices for morphing aircraft due to its advantages of pseudoelasticity, superelasticity, and shape memory effect. Precise and fast analysis of SMA has simultaneously become a key requirement for industrial applications. In this study, a user-defined material subroutine (UMAT) was implemented and successfully applied in a three-dimensional numerical simulation in ABAQUS based on the extended Boyd–Lagoudas model. In addition to the conventional detwinned martensite (Md) and austenite (A), twinned martensite (Mt) was also considered to model the practical transformation accurately. Then, the equivalent thermal strain approach was adopted to simplify the simulation complexity with UMAT. By resetting the thermal expansion coefficient, the thermal strain equivalent to the original phase transformation strain was generated. The approach was validated in two cases, showing consistent results with the extended Boyd–Lagoudas model and reduction in time consumption by 89.1%. Lastly, an active morphing skin integrating the single-range SMA and a stainless-steel plate was designed to realize two-way morphing. The calculated arc height variation of the skin was 3.74 mm with a relative error of 1.84% compared to the experimental result of 3.81 mm. The coupled use of UMAT and the equivalent thermal stress approach helped to reduce the challenge in modeling SMA.

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“…In the work of Leal et al (2015) a class/shape transformation approach relying on a standard genetic algorithm was adopted to define the size of the SMA actuators used to morph the wing to two predefined airfoil shapes considering simultaneously the aerodynamic loading. More recently, Rouchon et al (2018) proposed an optimization-based approach considering various criteria for the design of a morphing high lift flap consisting of numerous components and the SMA actuators. Two different cost functions entailing the consumed power and the mass of the flap were formulated.…”

Section: Introductionmentioning

confidence: 99%

Multi-objective optimization of a morphing structure incorporating shape memory alloy actuators

Machairas

Saravanos

2021

Journal of Intelligent Material Systems and Structures

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Morphing technology aims to improve the performance of structural components by drastically altering their shape in response to conflicting operational requirements. Thus, achieving the optimum operation of morphing structures is a rather challenging task which includes non-linear effects associated with the large deformations and rigid body motions, the actuator performance and the interactions between active and passive components. In this paper a formal optimization procedure is developed to provide the optimal design of a morphing structure with shape memory alloy actuators. The optimization of the morphing structure is formulated as a multi-objective problem aiming to concurrently optimize the passive structural components and the actuators. Subsequently, a multi-level optimization scheme is presented and implemented. Case studies prove the capability of the multi-objective optimization framework to produce robust designs of the morphing structure that simultaneously improve all performance metrics. Furthermore, it is illustrated that the proposed multi-level optimization scheme may produce similar optimal designs, compared with the conventional aggregate optimization scheme, but with significant computational gains.

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Optimized design of real-scale A320 morphing high-lift flap with shape memory alloys and innovative skin

Cited by 24 publications

References 21 publications

Numerical investigation of frequency-amplitude effects of dynamic morphing for a high-lift configuration at high Reynolds number

Numerical investigation of frequency-amplitude effects of dynamic morphing for a high-lift configuration at high Reynolds number

Design of a Morphing Skin with Shape Memory Alloy Based on Equivalent Thermal Stress Approach

Multi-objective optimization of a morphing structure incorporating shape memory alloy actuators

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