Multi-scale identification of elastic properties for anisotropic media through a global hybrid evolutionary-based inverse approach
GUILLAUMAT, Laurent
Laboratoire des Arts et Métiers ParisTech d'Angers - Procédés Matériaux Durabilité [LAMPA - PMD]
< Réduire
Laboratoire des Arts et Métiers ParisTech d'Angers - Procédés Matériaux Durabilité [LAMPA - PMD]
Langue
en
Communication dans un congrès avec actes
Ce document a été publié dans
ICCS20 - 20th International Conference on Composite Structures, ICCS20 - 20th International Conference on Composite Structures, 2017-09-04, Paris. 2017p. 199
Società Editrice Esculapio
Résumé en anglais
One of the main issues of composite materials is related to the difficulty ofcharacterising the full set of material properties at both mesoscopic and microscopic scales. Indeed, classical mechanical tests (traction/compression, ...Lire la suite >
One of the main issues of composite materials is related to the difficulty ofcharacterising the full set of material properties at both mesoscopic and microscopic scales. Indeed, classical mechanical tests (traction/compression, 3 or 4 points bending tests, etc.) are not able to provide the full set of 3D material properties of composites. Furthermore, these tests can provide only the in-plane elastic properties of the constitutive lamina (i.e at. the laminate mesoscopic scale). Therefore, in order to go beyond the main restrictions imposed by standard destructive tests, this work deals with the problem of characterising the material properties of a composite plate made of unidirectional fibre-reinforced laminae (at each characteristic scale), through a single non-destructive modal test performed at the macroscale, i.e. that of the specimen (the laminate). To face such a problem a general multi-scale identification strategy (MSIS) is proposed.The MSIS aims at identifying the constitutive properties at both micro and meso scales by exploiting the information restrained in the macroscopic dynamical response of the laminate (e.g. in terms of its eigenfrequencies). The MSIS relies on the one hand on the strain energy homogenisation technique of periodic media (for determining the effective elastic properties of the lamina as a function of the geometrical and material properties of the microscopic constitutive phases) and on the other hand on a special hybrid algorithm (genetic algorithm + gradient-based algorithm) in order to perform the solution search for the considered problem.The identification problem is stated as a constrained inverse problem (a least-squareconstrained problem), where the objective function depends upon both the measured and evaluated (from finite element analysis) natural frequencies of the laminated plate. In this background, the optimisation variables are both geometrical and material properties of the constitutive phases composing the representative volume element (RVE) of the composite.The effectiveness of the proposed approach will be proven through a campaign ofexperimental/numerical tests conducted on standard laminates made of unidirectional plies.< Réduire
Mots clés en anglais
Homogenisation
Composite materials
Optimisation
Modal analysis
Inverse problems
Identification
Composite material
Modal analysis
Origine
Importé de halUnités de recherche