Aeroelastic Tailoring using the Spars and Stringers Planform Geometry

François, Guillaume; Cooper, Jonathan E.

doi:10.2514/6.2017-1360

Cited by 8 publications

(7 citation statements)

References 36 publications

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“…All beam properties, including the second moment of area I 1 , are calculated from the GFEM static deflections due to tip loads as detailed in the next section. Aeroelastic analyses are then performed using the beam model (5), generating aeroelastic constraint values g 1 (6), external loads L (7) and associated gradients with respect to the beam model properties (8). The external loads are applied to the GFEM model for stress analysis (9), which outputs the stress constraint values g 2 (10) and their gradients with respect to the optimization variables ∂g 2 /∂v, and with respect to the applied loads ∂g 2 /∂L (11).…”

Section: Fig 1 Aeroelastic Optimization With Detailed Stress Constramentioning

confidence: 99%

“…One application of MDO is the design of aerostructures subject to aerodynamic, stress and aeroelastic constraints. Existing wing MDO implementations, such as those described in [1][2][3][4][5][6], tend to use three-dimensional global finite element models (GFEMs)…”

Section: Introductionmentioning

confidence: 99%

“…Identification procedures are used to determine beam properties yielding equivalent displacement responses to the full model. This approach was recently implemented in [6], to assess the effects of different spar and rib layouts on Euler-Bernoulli beam bending and torsion parameters. SwiftComp, an implementations of the mechanics of structural genome (MSG) theory developed by Yu [16], also uses this approach for the multi-scale modeling of heterogeneous composite structures, which cannot currently be handled by sectional analysis methods.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Slender-Wing Beam Reduction Method for Gradient-Based Aeroelastic Design Optimization

Stodieck¹,

Cooper²,

Neild³

et al. 2018

AIAA Journal

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The efficiency and scope of aeroelastic wing optimization strategies can be increased using analysis-specific structural idealizations, such as high-fidelity models for detailed stress analyses and low-fidelity models for aeroelastic analyses. In this work, a numerical method is presented that enables efficient and accurate reduction of a high-fidelity finite element model to a Timoshenko beam-based model with lumped masses. The result is a representation based on 13 independent physical beam stiffness parameters per element. The method also yields analytical beam sensitivities with respect to changes in the high-fidelity model. Using these, an approach is suggested for integrating the beam reduction method into a gradient-based multidisciplinary design optimization architecture. The reduction technique is demonstrated on a simplified wing-box and on the University of Bristol Ultra-Green aircraft configuration wing. The effects of unbalanced skin composite laminates, rotated internal ribs, varying wing taper and sweep, and wing boundary constraints on the wing stiffness are shown to be captured with sufficient accuracy for static and dynamic aeroelastic analysis purposes. The accuracy

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Section: Fig 1 Aeroelastic Optimization With Detailed Stress Constramentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Slender-Wing Beam Reduction Method for Gradient-Based Aeroelastic Design Optimization

Stodieck¹,

Cooper²,

Neild³

et al. 2018

AIAA Journal

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“…The ability of numerical models to accurately predict the flexibility of aerospace structures has therefore become central to further improve aeroelastic performance, e.g. aeroelastic tailoring [1][2][3]. Furthermore, considering the reliance on computer software and the critical choices that must be made during early design phases, the development of accurate, yet rapid, structural analysis methods is of paramount importance for aerospace applications [4].…”

Section: Introductionmentioning

confidence: 99%

Corotational Finite Element Formulation for Static Nonlinear Analyses with Enriched Beam Elements

et al. 2020

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The increasing reliance of aerospace structures on numerical analyses encourages the development of accurate, yet computationally efficient, models. Finite element (FE) beam models have, in particular, become widely-used approximations during preliminary design stages and to investigate novel concepts, e.g. aeroelastic tailoring. Over the last 50 years, developments in hp-FE methods based on elements of variable size (h) and polynomial degree (p) have helped reduce the computational cost of numerical analyses. Concurrently, many structures, including aircraft wings and wind turbine blades, have gradually increased in length, slenderness, and complexity. As a result, modern blades and wings regularly operate beyond the range of linear deformation, requiring non-linear analyses for which hp-FE methods are often not readily applicable. The aim of this paper is, therefore, to derive a co-rotational finite element formulation for enriched 3-, 4-and 5-noded beam elements, suitable for non-linear hp-FE refinement. To this end, we derive the mathematical formulation to incorporate enriched elements within the co-rotational FE beam framework. The proposed formulation is then validated against multiple non-linear benchmark problems and an experimental case study.

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“…Besides, Jutte et al (2014) have implemented few aeroelastic tailoring methods which also includes the usage of curvilinear rib and spar with varying orientation, tow steering composite laminates and also material and thickness grading on a CRM wing box [18]. Meanwhile, Francios et al (2017) have focused on the modification of spars and stringers planform geometry of a simple rectangular wing box model [19]. All in all, these research works have shown significant effect of curvilinear spars and ribs on the improvement of wing performance.…”

Section: Introductionmentioning

confidence: 99%

Parametric study of varying ribs orientation and sweep angle of un-tapered wing box model

Chan¹,

Harmin²,

Othman³

2018

IJET

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A simple un-tapered wing box model was considered to illustrate an aeroelastic tailoring of varying ribs orientation with respect to a range of sweep angles. This approach allows the bending-torsional modes characteristic to be altered hence offering possibility for improvement in aeroelastic performance without having to compromise its overall weight. Two cases of ribs orientation were considered for a range of sweep angles. The first case was by allowing one individual ribs to be orientated at a time and the second case considering all possible combination of ribs orientation. The finding shows that the torsional modes are greatly influenced by the rib orientation while the bending modes are not significantly affected. Therefore, this enable the frequency gap between the flutter modes to be altered; hence resulting into significant impact to aeroelastic performances. It has been found that for all the considered sweep angles, the varying ribs orientation can lead into an improvement of nearly 80-90% when compared to its corresponding baseline configuration. Therefore, this provides a leverage for an advancement in aeroelastic performance without having to penalize the total weight of the wing structure.

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Aeroelastic Tailoring using the Spars and Stringers Planform Geometry

Cited by 8 publications

References 36 publications

Slender-Wing Beam Reduction Method for Gradient-Based Aeroelastic Design Optimization

Slender-Wing Beam Reduction Method for Gradient-Based Aeroelastic Design Optimization

Corotational Finite Element Formulation for Static Nonlinear Analyses with Enriched Beam Elements

Parametric study of varying ribs orientation and sweep angle of un-tapered wing box model

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