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| Naji, M. |
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| Motta, Antonella |
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| Aletan, Dirar |
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| Mohamed, Tarek |
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| Ertürk, Emre |
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| Taccardi, Nicola |
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| Kononenko, Denys |
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| Petrov, R. H. | Madrid |
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| Alshaaer, Mazen | Brussels |
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| Bih, L. |
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| Casati, R. |
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| Muller, Hermance |
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| Kočí, Jan | Prague |
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| Šuljagić, Marija |
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| Kalteremidou, Kalliopi-Artemi | Brussels |
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| Azam, Siraj |
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| Ospanova, Alyiya |
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| Blanpain, Bart |
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| Ali, M. A. |
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| Popa, V. |
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| Rančić, M. |
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| Ollier, Nadège |
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| Azevedo, Nuno Monteiro |
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| Landes, Michael |
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| Rignanese, Gian-Marco |
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Joannès, Sébastien
Mines Paris - PSL
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (37/37 displayed)
- 2024Comprehensive Analysis of Fatigue / Creep Link in Thermoplastic Composites. ; Analyse approfondie du lien fatigue / fluage dans les composites thermoplastiques.
- 2024Tensile Characterization of Single Plant Fibres: a Benchmark Study
- 2024Influence of surface treatments and addition of a reactive agent on the properties of PLA/flax and PLA/bamboo compositescitations
- 2023Mechanisms of damage and fracture of aramid fibers: Focus on the role of microfibril cooperativity in fracture toughnesscitations
- 2023Mechanisms of damage and fracture of aramid fibers: Focus on the role of microfibril cooperativity in fracture toughnesscitations
- 2023How surface treatment and/or reactive agents allow closed loop recycling of PLA/Flax and PLA/Bamboo reinforced composites to be performed ?
- 2022Mechanical behaviour and durability of fibre-reinforced composites with organic matrices
- 2021Towards an understanding of the mechanical response of aramid fibers at the filament scale
- 2020Propagation of uncertainty from constituents to structural assessments in composite strength modelling
- 2020Propagation of uncertainty from constituents to structural assessments in composite strength modelling
- 2020Hybrid Effect in In-Plane Loading of Carbon/Glass Fibre Based Inter- and Intraply Hybrid Compositescitations
- 2020Uncertainty in Fibre Strength Characterisation Due to Uncertainty in Measurement and Sampling Randomnesscitations
- 2019Further Insights into the Fatigue of Hair Fibres through Statistical Analysis and Relevance to Hair Care Applications
- 2019Further Insights into the Fatigue of Hair Fibres through Statistical Analysis and Relevance to Hair Care Applications
- 2019Evaluation of Critical Parameters in Tensile Strength Measurement of Single Fibrescitations
- 2019Effect of uncertainty in characterization on the variability of fibre strength distributions
- 2019Effect of uncertainty in characterization on the variability of fibre strength distributions
- 2019Study of the influence of microscopic morphological fluctuations on thetransverse elastic behavior of unidirectional composites
- 2019Effect of through-thickness compressive stress and porosity on the tensile strength of carbon-fibre reinforced composites
- 2018Modelling the effect of porosity on the mechanical properties of unidirectional composites. The case of thick-walled pressure vessels
- 2018Manufacturing and performance of hybrid fabric reinforcements and their composites
- 2017A consistent experimental protocol for the strain rate characterization of thermoplastic fabricscitations
- 2016Modeling and definition of a statistically representative cell element. Application to a unidirectional short-fiber composite
- 2016Multiscale modelling of transport phenomena for materials with n-layered embedded fibres. Part II : Investigation of fibre packing effectscitations
- 2016Multiaxial mechanical behavior of aramid fibers and identification of skin/core structure from single fiber transverse compression testingcitations
- 2016Multiaxial mechanical behavior of aramid fibers and identification of skin/core structure from single fiber transverse compression testingcitations
- 2016Multiscale modelling of transport phenomena for materials with n-layered embedded fibres. Part I: Analytical and numerical-based approachescitations
- 2016Multiscale modelling of transport phenomena for materials with n-layered embedded fibres. Part II : Investigation of fibre packing effectscitations
- 2015Multi-axial mechanical behavior of aramid fibers and identification of skin/core structure from single fiber transverse compression testing
- 2014A concentration-dependent diffusion coefficient model for water sorption in compositecitations
- 2014A micromechanical damage characterization and the modeling of a mineral filled epoxy adhesivecitations
- 2013Analytical and finite element analyses on reliability of carbon fibre reinforced plastics
- 2013New experimental techniques and several micromechanical models for assessing the out-of-plan shear modulus properties of short glass fibre reinforced polyamide
- 2012Durability of a 3D woven composite assisted by finite element multi-scale modelling
- 2010The role of talc particles in a structural adhesive submitted to fatigue loadingscitations
- 2009Abaqus user element for an accurate modeling of adhesive joints on coarse meshes
- 2007Mechanical characterisation and numerical tool for the design of structural adhesive joints
Places of action
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document
Propagation of uncertainty from constituents to structural assessments in composite strength modelling
Abstract
In-service safety and reliable lifetime assessments are key challenges for high performance load bearing applications and require great care to be taken during their design. The design of composite material structures can be assisted by computational models. Many complex computational models have been developed for predicting the failure and lifetime analysis of structures. Critical structures such as high pressure composite cylinders require very accurate computational models, to understand the stochastic nature of the predicted structural response. The following issues limit the use of composite strength models for making reliable structural predictions: -The complex interaction between the fibres and matrix which governs the failure mechanism has not been accurately incorporated in composite strength models.-Lack of reliable constituent properties which are used as input for the models. There are several studies aimed at improving the state-of-the-art models. However, accurate constituent properties to be used as input for these models are rarely available. Authors usually do not comment on the uncertainty of the constituent properties reported, which is of major importance for stochastic simulations. Since fibres are the principal load bearing constituents of unidirectional composites, Islam et al. have quantified the uncertainty in the parameters of the fibre strength Weibull distribution arising during to the characterisation process, using a Monte-Carlo approach to capture the stochastic nature of the fibre strength behaviour. Strength of T700 carbon fibres, popularly used in composite pressure vessels, is used as reference. In this study, the influence of uncertainty in input fibre strength on model predictions has been evaluated. A composite strength model developed at Mines ParisTech was used. This model considers physical processes such as fibre failure and its interactions with the surrounding matrix. It was first developed in 2005 and has been improved over the years to simulate different loading conditions during service of composite structures such as pressure vessels. The strength and lifetime of a composite structure (coupon) is simulated under two different practical loading conditions (monotonically increasing and sustained loading) to elucidate the sensitivity of different structural responses to the input fibre strength distribution. The calculated uncertainties in the shape (m) and scale (sigma_0) parameters of the fibre strength Weibull distribution were used as input for the models. The results are listed as follows: 1) Monotonic loading: -The failure stress is seen to be significantly dependent on the scale parameter. The observed variation in the predicted failure stress is about 10% from the mean case, for an uncertainty of 10% in scale parameter. -The sensitivity of the model predictions to the shape parameter was insignificant. 2) Sustained loading: -The time to failure of the composite specimen was also found to be strongly affected by uncertainties in the scale parameter. The calculated uncertainty of 10% in the input scale parameter resulted in a variation in the predicted lifetime of about 15-30%. -The calculated uncertainty of 25% in the shape parameter resulted in a variation of about 16% in the predicted lifetime of the specimen. The structural behaviour predicted by the model is found to be highly sensitive to the uncertainties in the input fibre strength distribution which arise during characterisation. The understanding of the constituent properties and their characterisation process needs to be improved, in order to improve the reliability of computational model predictions, so that the predictions can be used with confidence in industrial applications.