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--- team:gdeliege [2015/08/11 11:02] – geoffrey
+++ team:gdeliege [2015/08/13 19:11] – [Education and Training] geoffrey
@@ Line 1: / Line 1: @@
-{{ :team:geoffrey_deliege.jpg?cache=120|Geoffrey}}
 ====== Geoffrey DELIEGE ======
-Research engineer
 ===== Contact =====
-//E-mail// : [[geoffrey.deliege@ulg.ac.be]] \\
+<WRAP left>
-//Phone// : +32 (0)4 366 95 91 \\
+{{ :team:geoffrey_deliege.jpg?cache=120|Geoffrey}}
-//Address// : Université de Liège - Aerospace and Mechanics \\
+</WRAP>
-Quartier Polytech 1 - B52/3 (office +2/541) \\
-Allée de la Découverte 13 A \\
+<code>
-B-4000 Liège, BELGIUM  \\
+Email : geoffrey.deliege@ulg.ac.be
+Phone : +32 (0)4 366 95 91
+Mail  : Aerospace and Mechanics
+        Quartier Polytech 1
+        Allée de la Découverte 13 A
+        B-4000 Liège, BELGIUM
+</code>
 ===== Research activities =====
-==== Composite materials ====
+<WRAP group>
+<WRAP third column>
-Carbon-Fibre-Reinforced Polymers (CFRP) are now widely used in aerospace industry
+<WRAP center box 100% centeralign>
-thanks to their high strength-to-weight ratio.
+[[team:gdeliege:composite|{{:team:gdeliege:labelcomposite.png}}]]\\
-However, the numerical simulation of CFRP laminates up to failure is not trivial:
+**[[team:gdeliege:composite|Composite materials]]**
-laminates have anisotropic mechanical properties and
+</WRAP>
-laminate damage results from a combination of microscopic mechanisms
+</WRAP>
-(fibre brittle failure, fibre-matrix debonding, matrix ductile failure and delamination)
+<WRAP third column>
-that are not easily described at a macroscopic level.
+<WRAP center box 150 centeralign>
+[[team:gdeliege:shearo|{{:team:gdeliege:labelshearo.png}}]]\\
+**[[team:gdeliege:shearo|Shearography]]**
+</WRAP>
+</WRAP>
+<WRAP third column>
+<WRAP center box 150 centeralign>
+[[team:gdeliege:espaint|{{:team:gdeliege:labelesp.png}}]]\\
+**[[team:gdeliege:espaint|Electrostatic painting]]**
+</WRAP>
+</WRAP>
+</WRAP>
-My objective was to implement a material model for composite plies with woven fibre
+<WRAP group>
-reinforcement in Metafor.
+<WRAP third column>
-This model is inspired by the meso-model
+<WRAP center box 100% centeralign>
-proposed by P. Ladevèze and O. Allix [1-2] for unidirectional
+[[team:gdeliege:mems|{{:team:gdeliege:labelmems.png}}]]\\
-composites as well as the 2D model for woven composites proposed by C. Hochard [3].
+**[[team:gdeliege:mems|Microelectromechanical systems]]**
+</WRAP>
+</WRAP>
+<WRAP third column>
+<WRAP center box 150 centeralign>
+[[team:gdeliege:nnm|{{:team:gdeliege:labelnnm.png}}]]\\
+**[[team:gdeliege:nnm|Nonlinear normal modes]]**
+</WRAP>
+</WRAP>
+<WRAP third column>
+<WRAP center box 150 centeralign>
+</WRAP>
+</WRAP>
+</WRAP>
-The idea is to describe the laminate as a stack of 3D orthotropic plies separated by 2D interfaces.
+===== Education and training =====
-In a direction parallel to the fibres,
-the plies are elastic and subject to brittle fracture;
-in shear, an elastoplastic behaviour is assumed and progressive damage is introduced.
-The 2D interfaces between the plies are elastic with progressive damage.
-Practical information on the
-[[doc:user:elements:volumes:ortho_hypo_materials|orthotropic materials]]
-and
-[[doc:user:elements:volumes:ortho_continuousdamage|damage evolution laws]]
-is available on the Metafor web page.
-One interesting feature of Ladevèze and Allix's work is that most parameters of the constitutive laws
+**M.Sc., 1997 - Physics Engineering, Université de Liège, Belgium** \\
-can be linked to physical quantities.
+Graduate Thesis title: //Raffinement adaptatif de types h et p pour le calcul des champs électromagnétiques.// \\
-Therefore, these parameters can be identified with suitable experimental tests.
+Supervisor: Prof. Willy Legros.\\
-{{ :team:gdeliege:stiffener2d.png?direct |Finite element simulation (Metafor) of an impacted stiffener made of woven carbon fibre laminate}}
+**Ph.D., 2003 - Electrotechnics, Katholieke Universiteit Leuven, Belgium** \\
+Title: //Flexible Implementation of the Finite Element Method Applied to 3D Coupled Problems Considering Convective Effects.// \\
+Supervisors: Prof. Kay Hameyer, Prof. Stefan Vandewalle.
-== References ==
+===== Skills and competences =====
-[1] P. Ladevèze, E. Le Dantec. //Damage modelling of the elementary ply for laminated composites.// Composites Science and Technology, Vol. 43, pp. 257-267, 1992 \\
+**Languages**
-[2] O. Allix, P. Ladevèze. //Interlaminar interface modeling for the prediction of laminate delamination.// Composite Structures, Vol. 22, pp. 235-242, 1992 \\
+  * French (mother tongue)
-[3] C. Hochard, P.-A. Aubourg, J.-P. Charles. //Modelling of the mechanical behaviour of woven-fabric CFRP laminates up to failure//. Composites Science and Technology, Vol. 61, pp. 221–230, 2001 \\
+  * English (advanced)
+  * Dutch (advanced)
-==== Shearography ====
+**IT**
-[[team:gdeliege:shearo]]
+  * software development : knowledge of C/C++, Python, Matlab, parallel programming tools (MPI), version control tools (Subversion)
+  * finite element software (university code ; Samcef ; marginal use of MagNet, ANSYS, LS-DYNA)
+  * Linux system management