Preliminary Aero-Elastic Optimization of a Twin-Aisle Long-Haul Aircraft with Increased Aspect Ratio

Toffol, Francesco; Ricci, Sergio

doi:10.3390/aerospace10040374

Cited by 8 publications

(4 citation statements)

References 36 publications

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“…A lighter wing reduces stress in the structure, improves fuel efficiency, and enhances overall performance. It is vital for striking the right balance among structural, aeroelastic, and material requirements in high aspect ratiohigh aspect ratio wing designs [1]. These wings endure substantial bending and torsional loads, demanding proper design to prevent failure.…”

Section: Introductionmentioning

confidence: 99%

High Aspect Ratio Composite Wings: Geometrically Nonlinear Aeroelasticity, Multi-Disciplinary Design Optimization, Manufacturing, and Experimental Testing

Farsadi,

Ahmadi,

Sahin

et al. 2024

Aerospace

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In the field of aerospace engineering, the design and manufacturing of high aspect ratio composite wings has become a focal point of innovation and efficiency. These long, slender wings, constructed with advanced materials such as carbon fiber and employing efficient manufacturing methods such as vacuum bagging, hold the promise of significantly lighter aircraft, reduced fuel consumption, and enhanced overall performance. However, to fully realize these benefits, it is imperative to address a multitude of structural and aeroelastic constraints. This research presents a novel aeroelastically tailored Multi-objective, Multi-disciplinary Design Optimization (MMDO) approach that seamlessly integrates numerical optimization techniques to minimize weight and ensure structural integrity. The optimized wing configuration is then manufactured, and a Ground Vibration Test (GVT) and static deflection analysis using the Digital Image Correlation (DIC) system are used to validate and correlate with the numerical model. Within the fully automated in-house Nonlinear Aeroelastic Simulation Software (NAS2) package (version v1.0), the integration of analytical tools offers a robust numerical approach for enhancing aeroelastic and structural performance in the design of composite wings. Nonlinear aeroelastic analyses and tailoring are included, and a population-based stochastic optimization is used to determine the optimum design within NAS2. These analytical tools contribute to a comprehensive and efficient methodology for designing composite wings with improved aeroelastic and structural characteristics. This comprehensive methodology aims to produce composite wings that not only meet rigorous safety and performance standards but also drive cost-efficiency in the aerospace industry. Through this multidisciplinary approach, the authors seek to underscore the pivotal role of tailoring aeroelastic solutions in the advanced design and manufacturing of high aspect ratio composite wings, thereby contributing to the continued evolution of aerospace technology.

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Section: Introductionmentioning

confidence: 99%

High Aspect Ratio Composite Wings: Geometrically Nonlinear Aeroelasticity, Multi-Disciplinary Design Optimization, Manufacturing, and Experimental Testing

Farsadi,

Ahmadi,

Sahin

et al. 2024

Aerospace

View full text Add to dashboard Cite

show abstract

“…Even though reduced-order and surrogate models have been applied to aeroelasticity problems for some time [13], especially to study unsteady nonlinear aeroelasticity problems that arise from unconventional features such as limit-cycle oscillations [14][15][16], their usage for MDO problems considering flutter is scarce [17][18][19] in the open literature, particularly for MDO problems considering aerodynamic performance and structural weight. For instance, Sohst et al [17] developed an MDO strategy that uses multi-fidelity solvers and surrogate models to design strut-braced and high-aspect-ratio wings considering flutter and stress constraints.…”

Section: Introductionmentioning

confidence: 99%

“…Cea and Palacios [18] implemented an optimization framework based on ROMs that couples different open-source codes, including SHARPy, for minimizing the mass of a flexible strut-braced wing while accounting for flutter speed as a constraint. Toffol and Ricci [19] developed a methodology combining in-house codes with surrogate models to optimize the structural layout of a conventional aircraft such that its mass is minimized while considering stress and flutter constraints. The application of surrogate models based on machine learning is scarcer.…”

Section: Introductionmentioning

confidence: 99%

A Study on the Surrogate-Based Optimization of Flexible Wings Considering a Flutter Constraint

Lunghitano,

Afonso,

Suleman

2024

Applied Sciences

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Accounting for aeroelastic phenomena, such as flutter, in the conceptual design phase is becoming more important as the trend toward increasing the wing aspect ratio forges ahead. However, this task is computationally expensive, especially when utilizing high-fidelity simulations and numerical optimization. Thus, the development of efficient computational strategies is necessary. With this goal in mind, this work proposes a surrogate-based optimization (SBO) methodology for wing design using a predefined machine learning model. For this purpose, a custom-made Python framework was built based on different open-source codes. The test subject was the classical Goland wing, parameterized to allow for SBO. The process consists of employing a Latin Hypercube Sampling plan and subsequently simulating the resulting wing on SHARPy to generate a dataset. A regression-based machine learning model is then used to build surrogate models for lift and drag coefficients, structural mass, and flutter speed. Finally, after validating the surrogate model, a multi-objective optimization problem aiming to maximize the lift-to-drag ratio and minimize the structural mass is solved through NSGA-II, considering a flutter constraint. This SBO methodology was successfully tested, reaching reductions of three orders of magnitude in the optimization computational time.

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“…Aeroelastic instabilities are some of the critical issues affecting the reliability and safety of military and commercial aircraft [1][2][3]. The tri-wing configuration is usually adopted for large swept-back hypersonic flight vehicles [4,5], such as the American X-37B, the Soviet Union's Buran, the British Hotol, and the German Sanger [6][7][8]. The aileron structure of such flight vehicles is thin, which may lead to the flutter behavior.…”

Section: Introductionmentioning

confidence: 99%

Flutter Optimization of Large Swept-Back Tri-Wing Flight Vehicles

Wang,

Qian,

et al. 2023

Aerospace

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The aerodynamic configuration of large swept-back tri-wings is generally adopted for hypersonic vehicles, but the structural stiffness of the ailerons is weak, which may lead to damage due to the flutter behavior. In the initial stage of structural design, studying the flutter characteristics of tri-wing flight vehicles is necessary and can provide the stiffness index of the tri-wing structural design. To assess the flutter characteristics of tri-wing flight vehicles efficiently, a rapid modeling technique of the finite element method was used in this paper. For the structural scheme of large swept-back tri-wing flight vehicles, a structural dynamic model was modeled using the rapid modeling technique, the unsteady aerodynamic was computed using the double-lattice method, and the flutter characteristics were analyzed using the P-K method. Variable parametric studies were conducted to evaluate the effects of the stiffness of the aileron skin, the stiffness of the control mechanism, and the mass distribution of the aileron on the flutter characteristics of large swept-back tri-wing flight vehicles. The results showed that the key flutter coupling modes of such vehicles are symmetric and anti-symmetric combinations of aileron rotation and torsion. Additionally, optimizing the control mechanism stiffness and mass distribution of the aileron could improve the flutter boundary, which can be helpful in the structural design of such vehicles. The flutter optimization technique effectively improved the flutter boundary, significantly enlarged the flight envelope, and accurately provided the stiffness index for the structural design of large swept-back tri-wing flight vehicles.

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Preliminary Aero-Elastic Optimization of a Twin-Aisle Long-Haul Aircraft with Increased Aspect Ratio

Cited by 8 publications

References 36 publications

High Aspect Ratio Composite Wings: Geometrically Nonlinear Aeroelasticity, Multi-Disciplinary Design Optimization, Manufacturing, and Experimental Testing

High Aspect Ratio Composite Wings: Geometrically Nonlinear Aeroelasticity, Multi-Disciplinary Design Optimization, Manufacturing, and Experimental Testing

A Study on the Surrogate-Based Optimization of Flexible Wings Considering a Flutter Constraint

Flutter Optimization of Large Swept-Back Tri-Wing Flight Vehicles

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