Due to the COVID19 crisis, the information below is subject to change,
in particular that concerning the teaching mode (presential, distance or in a comodal or hybrid format).
5 credits
30.0 h + 30.0 h
Q2
Teacher(s)
Latteur Pierre;
Language
French
Prerequisites
The prerequisite(s) for this Teaching Unit (Unité d’enseignement – UE) for the programmes/courses that offer this Teaching Unit are specified at the end of this sheet.
Main themes
See Chapter « Content » hereunder
Aims
At the end of this learning unit, the student is able to :  
1 
At the end of the course, the student will be able to

Content
NOTE IMPORTANTE : EN FONCTION DE LA SITUATION SANITAIRE, LE CONTENU, ACTIVITES ET METHODES D'EVALUATION POURRONT EVENTUELLEMENT ETRE ADAPTEES
Chap. 1: the laws of the MDS confirmed by the natural structures
Chap. 2: empiricism construction for millennia
Chap. 3: brief history of the resistance of materials
Chap. 4: building with the knowledge of the laws of nature
Chap. 5: designing the structures
Chap. 6: the categories of structures
Chap. 7: the general approach of calculating a structure
Chap. 8: mechanical properties of building materials
Chap. 9: actions on structures, load cases, load combinations
Chap. 10: strength and moment
Chap. 11: equilibrium, 1st order, 2nd order, second order, ...
Chap. 12: supports, hinges, isostaticity and hyperstaticity
Chap. 13: basic geometrical characteristics of sections: area, inertia, static moment
Chap. 14: notion of security, securty coefficients
Chap. 15: design of the elements subjected to normal force, thermal actions
Chap. 16: trusses
Projection of a film on the construction of the Millau Bridge
Chap. 17: Funicular arches
Chap. 18: Cables
Chap. 19: internal forces into the beams
Chap. 20: stresses in the beams and design criteria
Chap. 21: deformation of the beams
Chap. 22: biaxial flexion, composed flexion, notions of prestress
Chap. 23: stresses due to shear
Chap. 24: stresses due to torsion
(Chap. 25: continuous media and circle of Mohr)
(Chap. 26: rupture criteria, intrinsic curves)
Chap. 27: buckling
Chap. 28: energy, virtual works theorem, unity force theorem
Chap. 29: introduction to hyperstaticity
Chap. 1: the laws of the MDS confirmed by the natural structures
Chap. 2: empiricism construction for millennia
Chap. 3: brief history of the resistance of materials
Chap. 4: building with the knowledge of the laws of nature
Chap. 5: designing the structures
Chap. 6: the categories of structures
Chap. 7: the general approach of calculating a structure
Chap. 8: mechanical properties of building materials
Chap. 9: actions on structures, load cases, load combinations
Chap. 10: strength and moment
Chap. 11: equilibrium, 1st order, 2nd order, second order, ...
Chap. 12: supports, hinges, isostaticity and hyperstaticity
Chap. 13: basic geometrical characteristics of sections: area, inertia, static moment
Chap. 14: notion of security, securty coefficients
Chap. 15: design of the elements subjected to normal force, thermal actions
Chap. 16: trusses
Projection of a film on the construction of the Millau Bridge
Chap. 17: Funicular arches
Chap. 18: Cables
Chap. 19: internal forces into the beams
Chap. 20: stresses in the beams and design criteria
Chap. 21: deformation of the beams
Chap. 22: biaxial flexion, composed flexion, notions of prestress
Chap. 23: stresses due to shear
Chap. 24: stresses due to torsion
(Chap. 25: continuous media and circle of Mohr)
(Chap. 26: rupture criteria, intrinsic curves)
Chap. 27: buckling
Chap. 28: energy, virtual works theorem, unity force theorem
Chap. 29: introduction to hyperstaticity
Teaching methods
Due to the COVID19 crisis, the information in this section is particularly likely to change.
Lectures with the help of slides for the volume 1. Tutorials with the teaching assistants for the volume 2
Evaluation methods
Due to the COVID19 crisis, the information in this section is particularly likely to change.
Exam of about an hour, about the theoretical concepts of the course (PART I) + exam of about 3 hours with practical problems to solve (PART II). The theoretical exam may include a demonstration. For the PART II exam, students can only have a personal handwritten summary on a single, doublesided A4 sheet.
The success of both parties is required. If one of the two parties is in failure, the resulting score will be the minimum between the average score and 9/20.
An eliminatory question on very basic aspects of the course can be provided at the beginning of the exam. The final score will be 0/20 if this eliminatory question is not successful
Other information
A didactic software for calculating structures (see www.issd.be) is used during the course and TPs and is made available to students in computer room. Its use is highly recommended
Online resources
Available on Moodle
Bibliography
 Transparents du cours ;
 Vivement conseillé : « Introduction à l'analyse des structures », F. Frey et MA. Studer, Presses polytechniques et universitaires romandes ;
 Suggéré : « Analyse des structures et milieux continus), Volume 2 : Mécanique des structures, F. Frey, Presses polytechniques et universitaires romandes ;
 Suggéré (parties concernant les arcs et les câbles) : « calculer une structure, de la théorie à l'exemple », P. Latteur, Editions L'Harmattan/Academia.
Faculty or entity
GC
Programmes / formations proposant cette unité d'enseignement (UE)
Title of the programme
Sigle
Credits
Prerequisites
Aims
Minor in Construction
Bachelor in Engineering : Architecture
Master [120] in Chemical and Materials Engineering
Minor in Engineering Sciences: Construction (only available for reenrolment)
Specialization track in Construction