Multiscale surrogate-based framework for reliability analysis of unidirectional FRP composites

Omairey, Sadik L.; Dunning, Peter D.; Sriramula, Srinivas

doi:10.1016/j.compositesb.2019.106925

Cited by 27 publications

(16 citation statements)

References 36 publications

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“…As the demand for thermoset composites increases in number, size and complexity; the need for improved manufacturing techniques is vital. However, composites manufacturing is still a complex process that differs from alloys due to uncertainties inherited from their multi-phase compositing nature [4][5][6].…”

Section: Introductionmentioning

confidence: 99%

Novel multi-zone self-heated composites tool for out-of-autoclave aerospace components manufacturing

Jayasree

Omairey

Kazilas

2020

Science and Engineering of Composite Materials

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In this paper, a multi-zone self-heating composite tool is developed to manufacture out-of-autoclave complex and high-quality business jet lower wing stiffened composite panel. Autoclave manufacturing is regarded as a benchmark for manufacturing aerospace-grade composite parts. However, high accruing operational costs limit production rates thereby not being practical for smaller-scale companies. Therefore, significant work towards developing out-of-autoclave manufacturing is underway. In this study, a production line tool is developed with embedded heating fabric that controls temperature at the desired zones, replacing the need for autoclave cure. It investigates and identifies the optimal design parameters of the self-heating setup namely the placement of the heating fabric, zones, thermal management system, temperature distribution, heating rate and thermal performance using a thermal FEA model. The associated thermal characterisation of the tooling material and the part are measured for accurate simulation results. The design developed in this study will be used as production guideline for the actual tool.

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Section: Introductionmentioning

confidence: 99%

Novel multi-zone self-heated composites tool for out-of-autoclave aerospace components manufacturing

Jayasree

Omairey

Kazilas

2020

Science and Engineering of Composite Materials

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“…Performing RBDO for components that can be analysed analytically is simple compared with complex components that require numerical analysis with significant computational time. To demonstrate the feasibility of conducting an RBDO for numerically analysed components, an efficient FEA-based multi-scale reliability analysis developed by the authors (Omairey et al , 2019; Omairey et al , 2018) is used within a sequential deterministic and probabilistic optimisation strategy to reduce the mass of a composite component, while meeting a certain level of stiffness reliability, considering a wide range of uncertainties. An overview of this RBDO framework can be seen in Figure 2, and the required steps are explained in the following sections.…”

Section: Methodsmentioning

confidence: 99%

“…It takes the statistical information of uncertainties as an input and uses a large representative volume element (LRVE) that can model spatial variation of uncertainties, compared with a single RVE containing only one or two fibres, as shown in Figure 3. The LRVE is formed by correlating smaller RVEs in terms of material properties and geometric uncertainties, and employing a series of efficient surrogate models trained using a limited number of FE data points analysed using the periodic RVE homogenisation method [17], making it feasible to generate the large amount of probabilistic homogenised properties required to assess reliability accurately using Monte Carlo Simulation (MCS). Figure 3.…”

Section: Uncertainty Propagation Frameworkmentioning

confidence: 99%

“…Also, material property uncertainties at the ply level are related to uncertainties at smaller scales. For example, ply stiffness properties in a fibre-reinforced composite are influenced by uncertainties in the fibre and matrix material properties, fibre volume ratio and fibre stacking (Sriramula and Chryssanthopoulos, 2009; Shi et al , 2020; Omairey et al , 2019; Omairey et al , 2018; Zhou et al , 2016; Shaw et al , 2010). However, combining multi-scale modelling with RBDO for fibre-reinforced composite components has received little attention to date.…”

Section: Introductionmentioning

confidence: 99%

“…The aim of this research is to create an efficient multi-scale RBDO method for fibre-reinforced composite materials, that accounts for a wide range of uncertainties (including geometric uncertainties at the fibre-matrix scale), uses MCS, to avoid issues with nonlinear and multi-modal limit state functions, a non-deterministic optimisation method, to avoid local minima and potentially include discrete design variables and a finite element model at the component scale. This is achieved by extending and combining our previous surrogate-based framework for an off-line multi-scale uncertainty propagation (Omairey et al , 2019) with an on-line sequential optimisation and reliability analysis approach and adaptive local surrogate modelling strategy. A novel feature of our multi-scale framework is an inclusive FEA-based material representation unit, known as a large representative volume element (LRVE) that interpolates the effect of spatially correlated micro and meso-scale material and geometrical uncertainties, yet is computationally efficient for integration within a developed sequential RBDO framework.…”

Section: Introductionmentioning

confidence: 99%

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Multi-scale reliability-based design optimisation framework for fibre-reinforced composite laminates

Omairey

Dunning

Sriramula

2020

Self Cite

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Purpose The purpose of this study is to enable performing reliability-based design optimisation (RBDO) for a composite component while accounting for several multi-scale uncertainties using a large representative volume element (LRVE). This is achieved using an efficient finite element analysis (FEA)-based multi-scale reliability framework and sequential optimisation strategy. Design/methodology/approach An efficient FEA-based multi-scale reliability framework used in this study is extended and combined with a proposed sequential optimisation strategy to produce an efficient, flexible and accurate RBDO framework for fibre-reinforced composite laminate components. The proposed RBDO strategy is demonstrated by finding the optimum design solution for a composite component under the effect of multi-scale uncertainties while meeting a specific stiffness reliability requirement. Performing this using the double-loop approach is computationally expensive because of the number of uncertainties and function evaluations required to assess the reliability. Thus, a sequential optimisation concept is proposed, which starts by finding a deterministic optimum solution, then assesses the reliability and shifts the constraint limit to a safer region. This is repeated until the desired level of reliability is reached. This is followed by a final probabilistic optimisation to reduce the mass further and meet the desired level of stiffness reliability. In addition, the proposed framework uses several surrogate models to replace expensive FE function evaluations during optimisation and reliability analysis. The numerical example is also used to investigate the effect of using different sizes of LRVEs, compared with a single RVE. In future work, other problem-dependent surrogates such as Kriging will be used to allow predicting lower probability of failures with high accuracy. Findings The integration of the developed multi-scale reliability framework with the sequential RBDO optimisation strategy is proven computationally feasible, and it is shown that the use of LRVEs leads to less conservative designs compared with the use of single RVE, i.e. up to 3.5% weight reduction in the case of the 1 × 1 RVE optimised component. This is because the LRVE provides a representation of the spatial variability of uncertainties in a composite material while capturing a wider range of uncertainties at each iteration. Originality/value Fibre-reinforced composite laminate components designed using reliability and optimisation have been investigated before. Still, they have not previously been combined in a comprehensive multi-scale RBDO. Therefore, this study combines the probabilistic framework with an optimisation strategy to perform multi-scale RBDO and demonstrates its feasibility and efficiency for an fibre reinforced polymer component design.

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A method of obtaining the anisotropic complex moduli of carbon fibers by fitting

Guan

Tang²,

Zhao³

et al. 2023

Polymer Composites

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A novel fitting method of obtaining the anisotropic complex moduli of fibers based on the complex moduli of matrix and composites is presented. The complex longitudinal, transverse and in-plane shear moduli of the unidirectional T700 carbon fiber reinforced epoxy resin composite and the complex modulus of its matrix are measured using dynamic mechanical analysis. The predicted properties of the composite are calculated using the generalized method of cells (GMC). The complex axial, transverse and axial shear moduli of the carbon fibers are obtained by minimizing the sum of the squares of the modules of the difference between the test properties and predicted properties. Finally, the results of the experiment, finite element analysis, and GMC are compared. The results show that the complex axial and transverse moduli of the carbon fibers can be accurately evaluated, while the complex axial shear modulus cannot be accurately determined.

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Multiscale surrogate-based framework for reliability analysis of unidirectional FRP composites

Cited by 27 publications

References 36 publications

Novel multi-zone self-heated composites tool for out-of-autoclave aerospace components manufacturing

Novel multi-zone self-heated composites tool for out-of-autoclave aerospace components manufacturing

Multi-scale reliability-based design optimisation framework for fibre-reinforced composite laminates

A method of obtaining the anisotropic complex moduli of carbon fibers by fitting

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