Modelling of fibre steered plates with coupled thickness variation from overlapping continuous tows

Vertonghen, Lander; Castro, Saullo G.P.

doi:10.31224/osf.io/9bjy6

Cited by 3 publications

(5 citation statements)

References 41 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…(2) As explained in Wang et al (2020), for VAFW cylinders the thickness distribution of the kth ply given by h k (x) changes due to filament bending, filament shearing or any combination of both (Wang et al 2020), and the thickness increase is necessary to keep a constant volume (Castro et al 2019;Vertonghen and Castro 2021), leading to the following nonlinear dependence of h k (x) with the winding angle distribution (x):…”

Section: Design Parameterizationmentioning

confidence: 99%

Lightweight design of variable-angle filament-wound cylinders combining Kriging-based metamodels with particle swarm optimization

Wang

Almeida

Ashok

et al. 2022

Struct Multidisc Optim

Self Cite

View full text Add to dashboard Cite

Variable-angle filament-wound (VAFW) cylinders are herein optimized for minimum mass under manufacturing constraints, and for various design loads. A design parameterization based on a second-order polynomial variation of the tow winding angle along the axial direction of the cylinders is utilized to explore the nonlinear steering-thickness dependency in VAFW structures, whereby the thickness becomes a function of the filament steering angle. Particle swarm optimization coupled with three Kriging-based metamodels is used to find the optimum designs. A single-curvature Bogner–Fox–Schmit–Castro finite element is formulated to accurately and efficiently represent the variable stiffness properties of the shells, and verifications are performed using a general purpose plate element. Alongside the main optimization studies, a vast analysis of the design space is performed using the metamodels, showing a gap in the design space for the buckling strength that is confirmed by genetic algorithm optimizations. Extreme lightweight while buckling-resistant designs are reached, along with non-conventional optimum layouts thanks to the high degree of thickness build-up tailoring.

show abstract

Section: Design Parameterizationmentioning

confidence: 99%

Lightweight design of variable-angle filament-wound cylinders combining Kriging-based metamodels with particle swarm optimization

Wang

Almeida

Ashok

et al. 2022

Struct Multidisc Optim

Self Cite

View full text Add to dashboard Cite

show abstract

“…The main advantage of the smeared thickness approach regarding finite element modeling is that local thickening is simplified by a continuous thickness distribution over the plane, avoiding extremely refined meshes to model local thickening regions properly. The smeared thickness assumption for AFP panels has been compared with a discrete representation where all overlaps are modelled, leading to very close results [22,34].…”

Section: Fig 2 Afp Panels With (A) Local Thickening Pattern and (B) Constant Thickness Due To Cut-restart Technique [28]mentioning

confidence: 99%

“…Using a classical genetic algorithm, the panel geometry, fiber path and laminate stacking sequence are optimized in a single step to minimize the structural weight. The single-step optimization approach allows a straightforward description of the actual fiber orientations and steering angles, whereby the coupled thickness variation can be calculated based on constant volume requirements [4,22]. By employing a Lagrangian interpolation scheme and treating the reference fiber orientation angles as design variables, the variable thickness coupling is simplified once the steering angle is directly obtained.…”

Section: Introductionmentioning

confidence: 99%

“…Vescovini and Bisagni [24,25] also demonstrate a fast semi-analytical buckling model for the buckling of constant-stiffness composite panels with omega stiffeners. For variable-stiffness plates, Vertonghen and Castro [22] presented a suitable semi-analytical formulation for the purposes of the present study, which, however, cannot be used due to the stiffening plate elements, unless some strategy of connecting multiple domains is implemented, such as penalizing the strain energy [25][26][27]. Given the complications aforementioned complications with implementing a semi-analytical model, the linear buckling analyses are herein performed by means of finite elements with MSC Nastran ® .…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Design of Compressed Variable Stiffness Panels with Steering-thickness Coupling

Machado

Hernandes

Capacia

et al. 2021

AIAA Scitech 2021 Forum

View full text Add to dashboard Cite

Design of compressed variable stiffness panels with steering-thickness coupling genetic algorithm. Knowing the current state of angle distributions proved to be important while calculating the coupled thickness build-up. The optimization problem is constrained by the critical linear buckling load, herein calculated using finite elements with MSC Nastran ® , and by manufacturing and design constraints, such as the minimum steering radius of AFP and CTS and common design guidelines for laminated composites. The results are compared with an optimized baseline design using conventional straight-fibre laminates to quantify how the design is changed in terms of overall geometry, buckling loads and structural weight.

show abstract

“…This smeared out thickness distribution was the basis for Equation 1. Lander and Castro [10,11] compared the differences in modelling the exact thickness distribution vs. the smeared thickness distribution, demonstrating the good correlation and equivalence in buckling response of the smeared approach compared to a discrete representation of the overlaps.…”

Section: Thickness and Fiber Angle Distributionmentioning

confidence: 99%

Overlap-Stiffened Panels for Optimized Buckling Performance Under Minimum Steering Radius Constraints

Ummels¹,

Castro²

2020

Preprint

Self Cite

View full text Add to dashboard Cite

Recent research on variable stiffness laminates have shown both numerically and experimentally that further improvement on the buckling behaviour is possible by incorporating overlaps that result in variable thickness profiles, with the thickness non-linearly coupled with the local steering angle. We present the concept of overlap-stiffened panels, developing a design method that allows for incorporating higher-stiffness regions into individual plies of a variable-angle tow (VAT) laminate, taking advantage of the non-linear coupling between the tow steering angles and the local thickness. The proposed method naturally copes with minimum steering radius constraints of different manufacturing processes, and the present study considers two tow steering processes: automated fiber placement (AFP) and continuous tow shearing (CTS). The minimum radius constraint is satisfied by connecting two transition regions of thickness specified on each ply by means of circular fiber tow arcs, of which the radius of curvature always exceed the minimum manufacturing constraint. Each individual ply exploring the overlap-stiffened design is described using 5 design variables. Laminates made up of these overlap-stiffened plies are optimized for a maximum volume-normalized buckling performance under bi-axial compression, measured through FEM, by a genetic algorithm and benchmarked against a straight fiber panel optimized for the same load case. The conclusion can be drawn that both AFP and CTS overlap-stiffened VAT panels can at least achieve the double of the volume-normalized buckling performance of an optimized straight fiber panel, demonstrating the potential of the proposed design method.

show abstract

Modelling of fibre steered plates with coupled thickness variation from overlapping continuous tows

Cited by 3 publications

References 41 publications

Lightweight design of variable-angle filament-wound cylinders combining Kriging-based metamodels with particle swarm optimization

Lightweight design of variable-angle filament-wound cylinders combining Kriging-based metamodels with particle swarm optimization

Design of Compressed Variable Stiffness Panels with Steering-thickness Coupling

Overlap-Stiffened Panels for Optimized Buckling Performance Under Minimum Steering Radius Constraints

Contact Info

Product

Resources

About