In this work, multi-scale methods with strain softening are developed in the contexts of damage modeling for composite laminates and of buckling analyses in cellular materials. First, an anisotropic gradient–enhanced continuum damage model is embedded in a mean–field homogenization (MFH) process for elasto-plastic composites. The homogenization procedure is based on the newly developed incremental secant mean-field homogenization formulation, for which the residual stress and strain states reached in the phases upon a fictitious elastic unloading are considered as starting point to apply the secant method. The mean stress fields in the phases are then computed using isotropic secant tensors, which are naturally used to define the Linear ...
When studying the behavior of foams by multi-scale computational homogenization procedure, the micr...
International audienceThis work is concerned with the modeling of ductile damage behavior in composi...
Computational homogenization allows to let the macroscopic constitutive behavior of materials emerge...
This paper presents an incremental-secant mean- field homogenization (MFH) procedure for composites ...
AbstractThis paper presents an incremental-secant mean-field homogenization (MFH) procedure for comp...
This paper presents an incremental-secant mean-field homogenization (MFH) procedure for composites m...
The aim of this work is to develop an efficient multi–scale finite element framework to capture the ...
In this work, a gradient-enhanced mean-field homogenization (MFH) procedure is proposed for fiber re...
In this work, a gradient-enhanced homogenization procedure is proposed for fiber reinforced material...
AbstractIn this work we propose to study the behavior of cellular materials using a second-order mul...
A multiscale method is developed to study the failure of carbon fiber reinforced composites. In ...
The failure of carbon fiber reinforced composite laminates is studied using a multiscale method. ...
In this work, a gradient-enhanced mean-field homogenization (MFH) procedure is proposed for fiber re...
Classical finite element simulations face the problems of losing uniqueness and strain localization ...
Recently, the authors have presented an incremental-secant mean-field homogenisation (MFH) process f...
When studying the behavior of foams by multi-scale computational homogenization procedure, the micr...
International audienceThis work is concerned with the modeling of ductile damage behavior in composi...
Computational homogenization allows to let the macroscopic constitutive behavior of materials emerge...
This paper presents an incremental-secant mean- field homogenization (MFH) procedure for composites ...
AbstractThis paper presents an incremental-secant mean-field homogenization (MFH) procedure for comp...
This paper presents an incremental-secant mean-field homogenization (MFH) procedure for composites m...
The aim of this work is to develop an efficient multi–scale finite element framework to capture the ...
In this work, a gradient-enhanced mean-field homogenization (MFH) procedure is proposed for fiber re...
In this work, a gradient-enhanced homogenization procedure is proposed for fiber reinforced material...
AbstractIn this work we propose to study the behavior of cellular materials using a second-order mul...
A multiscale method is developed to study the failure of carbon fiber reinforced composites. In ...
The failure of carbon fiber reinforced composite laminates is studied using a multiscale method. ...
In this work, a gradient-enhanced mean-field homogenization (MFH) procedure is proposed for fiber re...
Classical finite element simulations face the problems of losing uniqueness and strain localization ...
Recently, the authors have presented an incremental-secant mean-field homogenisation (MFH) process f...
When studying the behavior of foams by multi-scale computational homogenization procedure, the micr...
International audienceThis work is concerned with the modeling of ductile damage behavior in composi...
Computational homogenization allows to let the macroscopic constitutive behavior of materials emerge...