5.00 crédits
30.0 h + 30.0 h
Q2
Enseignants
Delannay Laurent; Simar Aude;
Langue
d'enseignement
d'enseignement
Préalables
This is an advanced course about the mechanics of materials which is addressed to students having prior knowledge about continuum mechanics, linear theory of thermo-elasticity in three dimensions (tensor representation) as well as some basics of materials science (mechanical properties of amorphous and crystalline materials.)
Thèmes abordés
The course presents different mathematical models used by engineers in order to describe the mechanical reponse of deformable materials as well as their ability to sustain crack extensions. Each model is motivated from the physics and adaptations are suggested in order to account for non-linearity under finite strains, anisotropy of composite materials as well as the influence of temperature, environment and strain rate on the mechanical response. A systematic procedure is presented in order to select materials with optimized mechanical properties.
Acquis
d'apprentissage
d'apprentissage
A la fin de cette unité d’enseignement, l’étudiant est capable de : | |
1 |
At the end of the course, students will be able : · to solve basic problems using models allowing to predict mechanical responses of materials involving (hyper)elasticity and (visco)plasticity under finite strains as well as crack propagations, · to explain the physics underlying each model and the link between microstructure and macroscopic mechanical properties, · to explain the origin of various phenomena including anisotropy of composite materials, elastic spring back and necking of plastically deformed samples, residual stresses and creep. · to select a material with the best combination of mechanical properties based on the definition of performance indices, According to the classification of LO in the EPL programme, this activity contributes to the development and acquisition of the following LO: LO1.1, LO1.2, LO1.3, LO2.1, LO2.2, LO2.4, LO5.3, 5.4, 5.6
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Contenu
The course will cover the following topics :
· Materials selection procedure to achieve desired mechanical properties (material classes, performance indices)
· Complements of linear thermo(visco)elasticity : phase partitioning of strain and stress in composite materials (incl. eigenstrains and anisotropy)
· Contact stresses
· Plasticity and viscoplasticity (yield surface, J2 theory, elastic springback, dynamic loading, creep)
· Finite strains (hyperelasticity, plastic spin)
· Linear elastic fracture mechanics (toughness, stress intensity factor, crack opening displacement, limits of validity of LEFM, energy release rate)
- Fatigue (total life and crack propagation, materials factor affecting fatigue life)
· Materials selection procedure to achieve desired mechanical properties (material classes, performance indices)
· Complements of linear thermo(visco)elasticity : phase partitioning of strain and stress in composite materials (incl. eigenstrains and anisotropy)
· Contact stresses
· Plasticity and viscoplasticity (yield surface, J2 theory, elastic springback, dynamic loading, creep)
· Finite strains (hyperelasticity, plastic spin)
· Linear elastic fracture mechanics (toughness, stress intensity factor, crack opening displacement, limits of validity of LEFM, energy release rate)
- Fatigue (total life and crack propagation, materials factor affecting fatigue life)
Méthodes d'enseignement
The course will involve lectures, exercises and as well as PBL (project based learning) in small groups.
Face-to-face teaching will be priviledged but some activities may also be organized in distant mode if required.
Face-to-face teaching will be priviledged but some activities may also be organized in distant mode if required.
Modes d'évaluation
des acquis des étudiants
des acquis des étudiants
The final exam will asssess both the level of understanding of theoretical concepts and the student's skills to solve practical exercices. Students will be graded while accounting also for the outcome of the daily work (several projects and homeworks graded individually or per group).
The relative weight of the final exam: 40% for the year work and 60% for the written exam.
If the exam is organized in distant mode, the professors may complete the evaluation by an individual oral exam.
The use for homework of generative AI such as ChatGPT, Consensus, Perplexity,... is forbidden.
The relative weight of the final exam: 40% for the year work and 60% for the written exam.
If the exam is organized in distant mode, the professors may complete the evaluation by an individual oral exam.
The use for homework of generative AI such as ChatGPT, Consensus, Perplexity,... is forbidden.
Ressources
en ligne
en ligne
https://moodle.uclouvain.be/course/view.php?id=2040
Bibliographie
- Lecture notes written by the teachers provided on moodle
- Slides provided by the teachers provided on moodle
Support de cours
- Lecture notes and slides provided by the teachers on moodle
Faculté ou entité
en charge
en charge
MECA