A simple computational homogenization method for structures made of linear heterogeneous viscoelastic materials

Abstract In this paper, a numerical multiscale method is proposed for computing the response of structures made of linearly non-aging viscoelastic and highly heterogeneous materials. In contrast with most of the approaches reported in the literature, the present one operates directly in the time domain and avoids both defining macroscopic internal variables and concurrent computations at micro and macro scales. The macroscopic constitutive law takes the form of a convolution integral containing an effective relaxation tensor. To numerically identify this tensor, a representative volume element (RVE) for the microstructure is first chosen. Relaxation tests are then numerically performed on the RVE. Correspondingly, the components of the effective relaxation tensor are determined and stored for different snapshots in time. At the macroscopic scale, a continuous representation of the effective relaxation tensor is obtained in the time domain by interpolating the data with the help of spline functions. The convolution integral characterizing the time-dependent macroscopic stress–strain relation is evaluated numerically. Arbitrary local linear viscoelastic laws and microstructure morphologies can be dealt with. Implicit algorithms are provided to compute the time-dependent response of a structure at the macroscopic scale by the finite element method. Accuracy and efficiency of the proposed approach are demonstrated through 2D and 3D numerical examples and applied to estimate the creep of structures made of concrete.

[1]  Pierre Suquet,et al.  Effective behavior of linear viscoelastic composites: A time-integration approach , 2007 .

[2]  A. Matzenmiller,et al.  Micromechanical modeling of viscoelastic composites with compliant fiber–matrix bonding , 2004 .

[3]  N. Laws,et al.  Self-consistent estimates for the viscoelastic creep compliances of composite materials , 1978, Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences.

[4]  M. Berveiller,et al.  A new class of micro–macro models for elastic–viscoplastic heterogeneous materials , 2002 .

[5]  Julien Yvonnet,et al.  The reduced model multiscale method (R3M) for the non-linear homogenization of hyperelastic media at finite strains , 2007, J. Comput. Phys..

[6]  A. Zaoui,et al.  Structural morphology and relaxation spectra of viscoelastic heterogeneous materials , 2000 .

[7]  Hassan Hassanzadeh,et al.  Comparison of different numerical Laplace inversion methods for engineering applications , 2007, Appl. Math. Comput..

[8]  P. A. Turner,et al.  Self-consistent modeling of visco-elastic polycrystals: Application to irradiation creep and growth , 1993 .

[9]  Véronique Favier,et al.  Micromechanical modeling of the elastic-viscoplastic behavior of polycrystalline steels having different microstructures , 2004 .

[10]  P. Ponte Castañeda,et al.  New variational principles in plasticity and their application to composite materials , 1992 .

[11]  S. Maghous,et al.  A micromechanical approach to elastic and viscoelastic properties of fiber reinforced concrete , 2010 .

[12]  Frank T. Fisher,et al.  Viscoelastic interphases in polymer–matrix composites: theoretical models and finite-element analysis , 2001 .

[13]  Keith W. Jones,et al.  Synchrotron computed microtomography of porous media: Topology and transports. , 1994, Physical review letters.

[14]  Zvi Hashin,et al.  Complex moduli of viscoelastic composites—I. General theory and application to particulate composites , 1970 .

[15]  Anton Matzenmiller,et al.  Finite element analysis of viscoelastic composite structures based on a micromechanical material model , 2008 .

[16]  Frédéric Feyel,et al.  Multiscale FE2 elastoviscoplastic analysis of composite structures , 1999 .

[17]  H. Rothert,et al.  Formulation and implementation of three-dimensional viscoelasticity at small and finite strains , 1997 .

[18]  P. Mangat,et al.  A theory for the creep of steel fibre reinforced cement matrices under compression , 1985 .

[19]  Michael D. Gilchrist,et al.  Numerical inversion of the Laplace–Carson transform applied to homogenization of randomly reinforced linear viscoelastic media , 2007 .

[20]  L. C. Brinson,et al.  Comparison of micromechanics methods for effective properties of multiphase viscoelastic composites , 1998 .

[21]  R. Masson,et al.  Effective properties of linear viscoelastic heterogeneous media: Internal variables formulation and extension to ageing behaviours , 2009 .

[22]  R. Taylor,et al.  Thermomechanical analysis of viscoelastic solids , 1970 .

[23]  M. Berveiller,et al.  Micromechanical modeling coupling time-independent and time-dependent behaviors for heterogeneous materials , 2009 .

[24]  Julien Yvonnet,et al.  Numerically explicit potentials for the homogenization of nonlinear elastic heterogeneous materials , 2009 .

[25]  Vincent Legat,et al.  General mean-field homogenization schemes for viscoelastic composites containing multiple phases of coated inclusions , 2006 .

[26]  G. Weng,et al.  The influence of inclusion shape on the overall viscoelastic behavior of composites , 1992 .

[27]  William T. Weeks,et al.  Numerical Inversion of Laplace Transforms Using Laguerre Functions , 1966, JACM.

[28]  Zvi Hashin,et al.  Viscoelastic Behavior of Heterogeneous Media , 1965 .