Mechanics of Materials
Áreas Científicas |
Classificação |
Área Científica |
OFICIAL |
Solid Mechanics |
Ocorrência: 2023/2024 - 2S
Ciclos de Estudo/Cursos
Sigla |
Nº de Estudantes |
Plano de Estudos |
Anos Curriculares |
Créditos UCN |
Créditos ECTS |
Horas de Contacto |
Horas Totais |
EM |
107 |
Plano de Estudos |
2 |
- |
6 |
75 |
162 |
Docência - Responsabilidades
Língua de trabalho
Portuguese
Objetivos
At the end of the course the student should:
- Identify the components of the state of stress and state of strain at a point;
- Know how to represent the axial load, torque, shear and bending-moment diagrams;
- Know how to calculate stresses and deformations in simple structural components;
- Know how to solve statically indeterminate problems using the superposition method.
Resultados de aprendizagem e competências
Chapter 1
Know the concepts of normal stress, shear stress and state of stress at a point.
Chapter 2
Know the concepts of normal and shear strain. Draw the axial load diagram. Evaluate the stress and the deformation in members under axial loading. Solve statically indeterminate problems as well as problems involving temperature changes.
Chapter 3
Draw the torsion moment diagram. Evaluate stresses and deformations in circular shafts and in thin-walled members. Solve statically indeterminate problems.
Chapter 4
Evaluate stresses and deformations in symmetrical beams under pure bending. Know the concept of anticlastic curvature. Evaluate stresses in beams under unsymmetrical bending.
Chapter 5
Draw the shear and bending moment diagrams. Know the concept of shear center and determine its location in thin-walled beams whit at least one symmetry axis. Evaluate shear stresses in thin-walled beams.
Chapter 6
Determine the equation of the elastic curve. Solve statically indeterminate problems.
Modo de trabalho
Presencial
Programa
1. Introduction to the Mechanical of Materials; Concept of Stress
2. Stress and Strain - Axial Loading
3. Torsion
4. Pure Bending
5. Transverse Loading
6. Deflection of Beams
Bibliografia Obrigatória
Beer, Johnston, DeWolf and Mazurek; Mechanics of Materials, seventh edition, McGraw-Hill, 2015. ISBN: 978-0-07-339823-5
A. Valido e J. Duarte Silva; Introdução à Extensometria Eléctrica de Resistência, 1997
Métodos de ensino e atividades de aprendizagem
Theoretical-Practical classes:
Theoretical exposure of the subjects and problems solving by students;
Practical-laboratorial classes:
Realization of practical works using experimental stress analysis and problems solving by students.
Palavras Chave
Technological sciences > Engineering > Mechanical engineering
Tipo de avaliação
Distributed evaluation without final exam
Componentes de Avaliação
Designation |
Peso (%) |
Teste |
60,00 |
Trabalho escrito |
15,00 |
Trabalho laboratorial |
25,00 |
Total: |
100,00 |
Componentes de Ocupação
Designation |
Tempo (Horas) |
Estudo autónomo |
70,00 |
Frequência das aulas |
75,00 |
Trabalho laboratorial |
20,00 |
Total: |
165,00 |
Obtenção de frequência
Distributed assessment without final exam: Performance of 2 tests – TE
Performance of 4 problem sheets - FP
Performance of 4 laboratory works – TL
Fórmula de cálculo da classificação final
Final grade = 0,6*TE + 0,25*TL + 0,15*FP
where:
TE – Average of the 2 tests;
FP – Average of the 4 problem sheets; TL – Average of the 4 lab assignments.Conditions for approval in the course: Mandatory completion and discussion of the 4 lab woks;
Average of the 2 tests >= 8,0 values;
Final grade >= 9,5 values;
Melhoria de classificação
The grade improvement is done in the Appeal Season by registering in the Academic Division.
Observações
Students who have not obtained approval in the continuous evaluation, at the time of examination recover the written component (TE + FP);
The problem sheets are performed in group;
The lab assignments and its discussion are done in group;
The report of one of the lab assignments is written in English.
Attendance hours: Available on moodle
Assessment datas: Available on moodle