Étude et modélisation du comportement en compression du bois sous sollicitations d'impacts / Experimental investigation and numerical modelling of wood under compressive impact loadings

Wouts, Jérémy

05 September 2017

Le bois est un matériau cellulaire naturel et excellent absorbeur d’énergie. Employé au sein de structures du type limiteur d’impact, il subit de nombreux phénomènes lors d’un cas de chute. Une large campagne expérimentale est réalisée afin d’analyser les réponses en compression du hêtre et de l’épicéa, en fonction de la direction de sollicitation, de la vitesse de déformation pour la plage [0.001-600] s−1 et de deux types de restrictions latérales qualifiées d’extrêmes. La direction longitudinale se révèle la plus sensible à la vitesse ainsi qu’au type de restrictions latérales et les conséquences sur la capacité d’absorption d’énergie du bois sont alors significatives. Par ailleurs, les protocoles développés ont vocation à être déclinés pour un large panel d’essences aux propriétés mécaniques variées. Un modèle matériau élastoplastique, isotrope transverse et sensible à la vitesse de déformation est élaboré à l’aide des techniques multi-échelles et de la micromécanique. Les propriétés élastiques macroscopiques sont estimées à l’aide du schéma d’homogénéisation de Mori-Tanaka à partir de données issues de la microstructure. Un critère de type Gurson étendu reposant sur l’approche micromécanique de l’endommagement ductile est employé pour retranscrire le comportement non linéaire, la densification et le caractère compressible du bois. Des paramètres de dégradation découplés du critère sont appliqués selon la direction longitudinale. La modélisation proposée repose sur une description simplifiée du bois et les résultats numériques associés illustrent la bonne capacité du modèle à reproduire les différentes réponses observées lors d’un cas de chute. / Wood is a natural cellular material, which is widely and advantageously used as shock absorber for the transport of radioactive materials. Accident situations are evaluated based on the 9 m drop test, which allows us to observe the complex crushing behavior of wood. A compressive experimental study is conducted on spruce and beech wood species over a large range of strain rates (from 0.001 to 600 s−1) to investigate the effect of the loading direction and of two extreme lateral confinements. The longitudinal direction is the most sensitive to the effect of strain rate and of lateral confinements which have significant consequences on the energy absorption. Besides, the experimental investigation can be adapted to various wood species with very different mechanical properties. A strain rate dependent elastoplastic model with transversal isotropy is developed using multi-scale and micromechanics techniques. The elastic macroscopic properties of wood are estimated with a Mori-Tanaka scheme and information extracted from the microstructure. The Gurson type criterion based on the micromechanical approach of the ductile damage is used in order to describe the non linear behavior of wood, its densification regime and its compressibility as well. Additionally, uncoupled degradation parameters are applied to reproduce the failure mechanisms involved in the longitudinal response. A simplified description of wood is used within the modeling and the numerical results exhibit the good ability of the model to reproduce the various wood responses during an accident situation.

Bois

Absorption d’énergie

Dynamique

Shpb

Compression

Effet de vitesse

Confinement

Homogénéisation

Micromécanique

Gurson

Plasticité

Ls-Dyna

Wood

Energy absorption

Dynamic

Shpb

Compression

Strain rate effect

Confinement

Homoneization

Micromechanics

Gurson

Plasticity

Ls-Dyna

Modelling of failure

Björklund, Oscar

January 2008

<p>This report is a review of some failure models today used for determine failure in thin sheets of high strength steels. Focus has been given on phenomenlogical models and only some simple simulations have been carried out. The phenomenlogical models that have been summarized here are of four different categories, namely stress based, strain based, combined stress and strain based and damaged models. However, the simulations have only been preformed for some of the models.</p>

failure modelling

phenomelogical

Cockcroft-Latham

Bressan-Williams

Gurson

Johnson-Cook

Wilkins

Damage

LS-DYNA

Engineering mechanics

Teknisk mekanik

Modelling of failure

Björklund, Oscar

January 2008

This report is a review of some failure models today used for determine failure in thin sheets of high strength steels. Focus has been given on phenomenlogical models and only some simple simulations have been carried out. The phenomenlogical models that have been summarized here are of four different categories, namely stress based, strain based, combined stress and strain based and damaged models. However, the simulations have only been preformed for some of the models.

failure modelling

phenomelogical

Cockcroft-Latham

Bressan-Williams

Gurson

Johnson-Cook

Wilkins

Damage

LS-DYNA

Engineering mechanics

Teknisk mekanik

Prediction of DP steel fracture by FEM simulationsusing an advanced Gurson model

Fansi, Joseph

02 July 2013

This numerical investigation of an advanced Gurson-Tvergaard-Needleman (GTN) model is an extension of the original work of Ben Bettaieb et al. (2011). The model has been implemented as a user-defined material model subroutine (VUMAT) in the Abaqus/explicit FE code. The current damage model extends the previous version by integrating the three damage mechanisms: nucleation, growth and coalescence of voids. Physically based void nucleation and growth laws are considered, including an effect of the kinematic hardening. These new contributions are based and validated on experimental results provided by high-resolution X-ray absorption tomography measurements. Also, the numerical implementation of the kinematic hardening in this damage extension has obliged to readapt the classical triaxiality definition. Besides, a secondary fracture initiation criterion based on the ultimate average inter-cavities distance has been integrated to localize and quantify with good accuracy the strain distribution just before the material fails apart. The current damage model is applied in industrial conditions to predict the damage evolution, the stress state and the fracture initiation in various tensile thin flat sheet geometries and the cross-die drawing tests.

[SPI:OTHER] Engineering Sciences/Other

Formability

Gurson model

Plasticity anisotropy

Finite element

Sheet flange damages

Fracture initiation

Locally enhanced voronoi cell finite element model (LE-VCFEM) for ductile fracture in heterogeneous cast aluminum alloys

Hu, Chao

07 January 2008

No description available.

Engineering, Mechanical

Voronoi cell finite element model

Ductile fracture

Matrix cracking

Void coalescence

Numerical Modeling of Ductile Fracture

Zhou, Jun

January 2013

No description available.

Mechanics

Mechanical Engineering

Ductile fracture

damage accumulation

Johnson-Cook models

stress triaxiality

Lode angle

plastic flow

residual stress

crack initiation and growth

void growth

shear damage

Gurson

Modélisation micromécanique de la croissance et de la percolation de pores sous pression dans une matrice céramique à haute température

Vincent, Pierre-Guy

12 November 2007

Ce travail vise à la construction d'un modèle élastoplastique endommageable pour une céramique poreuse à deux populations de pores saturés : le combustible nucléaire d'oxyde d'uranium fortement irradié et à haute température. La démarche suivie consiste en une approche multi-échelle basée sur l'hypothèse de séparation des échelles entre les deux populations de cavités (pores intragranulaires sphériques et pores intergranulaires ellipsoïdaux) et sur celle de l'isotropie macroscopique. Le modèle élastoplastique endommageable proposé traite séparément de l'élasticité, de la surface de plasticité et de l'évolution des paramètres internes du modèle avec le chargement. La prise en compte de pressions différentes dans chaque population de cavités est effectuée pour les trois régimes élasticité-plasticité-endommagement.

Milieux poreux

oxyde d'uranium

combustible

homogénéisation

approche multi-échelle

élasticité

plasticité

endommagement

critère de Gurson

approches variationnelles

cavités ellipsoïdales

fissures

éléments finis

transformée de Fourier rapide

zones cohésives

cellules de Voronoï