Abstract
In this paper, a mean field homogenization (MFH) method is compared to the hyper-reduction (HR) method. The homogenization of concern aims to forecast the mechanical response of viscoelastic–viscoplastic composites undergoing small strains. Reference results are provided by the usual finite element method (FEM) applied to an unit cell problem. In both methods the microscopic strain fields are represented using a reduced basis. In MFH it is an eigenstrain basis in the vocabulary of [17]. This basis is spanned by the stress-free strains introduced by Eshelby [5]. In the HR method the reduced basis is spanned by modes. It can be created by the proper orthogonal decomposition (POD) method or the APHR method [19]. MFH and HR methods are compared in terms of equation formulation, accuracy and computational time. The accuracy of both global and local results are compared. We consider as MFH local-results the global ones, as if they are uniform in the matrix of the composite. It turns out that the HR method provides simulations of accuracy and computational complexity between the MFH method and the full-field FEM. The HR model contains a reduced mesh named reduced domain (RD). This requires to reconstruct the internal variables by using the Gappy POD. We point out that the APHR method provides unrealistic non-smooth modes when the reconstruction of the internal variables is performed only outside the RD and not inside the RD.
Highlights
Polymer matrix composites reinforced with glass fibers are widely used in a variety of technological applications because of the enhanced mechanical properties, the stiffness and the strength
Accurate predictions of the macroscopic mechanical response of such composite materials may be derived from full field calcula tion of the local stresses and strains throughout a statistically representative volume element (RVE) of the microstructure subjected to periodic boundary condi tions
We studied a technique for the construction of re duced model from a finite element model for coupled VE VP solids
Summary
Polymer matrix composites reinforced with glass fibers are widely used in a variety of technological applications because of the enhanced mechanical properties, the stiffness and the strength. Concerning the homogenization strategy applied in this work namely MFH method, we note that this technique is based on the interaction laws between the different phases It provides an approximative effective response, as well as a description of mechanical fields within the phases in terms of volume averages, requiring a low computational cost. The mean field methods were first proposed for composites having linear elastic or thermo elastic constituents The generalization of this homogenization procedure for nonlinear two phase composites is based on the lin earization of the local constitutive laws and the per phase unifor mization of the mechanical properties. The paper is organized in the following manner: Section 2 intro duces the coupled viscoelastic viscoplastic constitutive law, the formulation of the equilibrium equations related to the HR method and the APHR algorithm used to generate the RB.
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