Unit INTRODUCTORY MECHANICS
- Course
- Industrial engineering
- Study-unit Code
- 70100406
- Curriculum
- In all curricula
- Teacher
- Emanuela Speranzini
- Teachers
-
- Emanuela Speranzini
- Hours
- 54 ore - Emanuela Speranzini
- CFU
- 6
- Course Regulation
- Coorte 2021
- Offered
- 2022/23
- Learning activities
- Caratterizzante
- Area
- Ingegneria dei materiali
- Academic discipline
- ICAR/08
- Type of study-unit
- Obbligatorio (Required)
- Type of learning activities
- Attività formativa monodisciplinare
- Language of instruction
- Italian
- Contents
- The aim of this course is to explore, in some detail, the mechanical properties of materials and structures and to develop appropriate mathematical models to describe and predict the engineering behaviour of the structures. By the end of the course student will be familiar with modern approaches to determining the strength and stiffness of materials and the application of these properties in practice.
1. Anlysis of determinate structures (single- and multi-beam structures).
2. Definition and analysis of Trusses (determinate).
5. The theory of the Beam (De Saint Venant): stresses in beams (produced by axial load, bending moment, shearing force and Torque).
6. Centroids, first moments, second moments, radii of giration, principal directions, product of inertia.
7. Coefficient of Poisson, Young's modulus, isotropic materials. Hooke's law. - Reference texts
- 1. Erasmo Viola - Esercitazioni di Scienza delle costruzioni - vol 1° 1993 Pitagora Editrice Bologna Erasmo Viola - Esercitazioni di Scienza delle costruzioni - vol 2° 1985 Pitagora Editrice Bologna
2. Riccardo Baldacci - Scienza delle costruzioni: Fondamenti di meccanica dei solidi - vol 1° 1970 UTET
3. Riccardo Baldacci - Scienza delle costruzioni: Fondamenti di meccanica delle strutture - vol 2° 1976 UTET
4. Michele Capurso - Lezioni di Scienza delle costruzioni - 1971 Pitagora editrice
5. James M. Gere, Stephen P. Timoshenko Mechanics of Materials (Inglese), 1991, o edizioni successive.
6. Andrew Pytel, Jaan Kiusalaas, Engineering Mechanics: Statics, 1998. - Educational objectives
- The exam should demonstrate the student's familiarity with the relevant literature on the subject and the ability to conduct analysis/research, interpret the findings and draw conclusions. The exam should be written in a coherent form adhering to academic writing conventions.
- Prerequisites
- Rational Mechanics
- Teaching methods
- Lectures and seminars will be delivered by the module tutor.
- Other information
- Disabled students and/or with DSA, can contact the teacher of this course directly because she is the contact professor for disability and DSA in Engineering Department.
- Learning verification modality
- Interview and written exam (closed book).
The examinations should be taken after the end of the course. The student will be examined on the topics of the course provided to the qualifying examination committee. The student will be examined also on general knowledge of mechanics of materials as well as in two specialized areas of determinate structures - Extended program
- The aim of this course is to explore, in some detail, the mechanical properties of materials and structures and to develop appropriate mathematical models to describe and predict the engineering behaviour of the structures. By the end of the course student will be familiar with modern approaches to determining the strength and stiffness of materials and the application of these properties in practice.
1. Anlysis of determinate structures (single- and multi-beam structures).
2. Definition and analysis of Trusses (determinate).
5. The theory of the Beam (De Saint Venant): stresses in beams (produced by axial load, bending moment, shearing force and Torque).
6. Centroids, first moments, second moments, radii of giration, principal directions, product of inertia.
7. Coefficient of Poisson, Young's modulus, isotropic materials. Hooke's law