Materials

Code:

MI02

Sigla:

MAT

Áreas Científicas
Classificação	Área Científica
CNAEF	Metallurgy and Metal Mechanics

Ocorrência: 2021/2022 - 1S

Ativa?	Yes
Unidade Responsável:	Departamento de Engenharia Mecânica
Curso/CE Responsável:	Professional Technical Higher Education Course in Industrial Maintenance

Ciclos de Estudo/Cursos

Sigla	Nº de Estudantes	Plano de Estudos	Anos Curriculares	Créditos UCN	Créditos ECTS	Horas de Contacto	Horas Totais
TSPMI	17	Plano de Estudos	1	-	6	60	162

Docência - Responsabilidades

Docente	Responsabilidade
Catarina Ferreira dos Santos

Docência - Horas

Theorethical and Practical :

4,00

Type	Docente	Turmas	Horas
Theorethical and Practical	Totais	1	4,00
Theorethical and Practical	Catarina Ferreira dos Santos		4,00

Língua de trabalho

Portuguese
Obs.: Português/Inglês

Objetivos

Promoting knowledge of different types of materials used in mechanical engineering: metals, polymers, ceramics and composites and the relationship between their properties, structure, process and service performance. Recognizing the need for design with new materials.

Resultados de aprendizagem e competências

1. Lectures with presentation of concepts and correlation between different types of materials. Typical cases and examples of materials and their application are also discussed. 2. Lab-Practice classes with solving problems. Experimental work in the laboratory is performed in-group, including testing of materials characterization and mechanical testing. Discussion of the reports of the experimental work is included.
Continuous assessment consists of tests and ten laboratory assignments. The assessment can also be made through a final exam.

Modo de trabalho

Presencial

Programa

1. Introduction
Classification of materials. Advanced materials. Modern materials’ needs.
Interatomic bonding. Primary interatomic bonds. Secondary bonding or van der Waals bonding. The structure of crystalline solids. Fundamental concepts. Unit cells. Metallic crystal structures. Density. Polymorphism and allotropy. Noncrystalline solids.
Crystal Systems. Point coordinates. Crystallographic directions. Crystallographic planes. Linear and planar densities. Close-packed crystal structures
Polycrystalline materials. Anisotropy. X-ray diffraction: determination of crystal structures.
Imperfections in solids. Vacancies and self-interstitials. Impurities in solids. Dislocations and strengthening mechanisms. Characteristics of dislocations. Plastic deformation of polycrystalline materials. Bulk or volume defects. Microscopic techniques.
Diffusion. Diffusion mechanisms. Steady-state diffusion. Nonsteady-state diffusion
Phase diagrams. Solubility limit. Phases. Microstructure. Phase equilibria. One-component (or unary) phase diagrams. Binary isomorphous systems. Interpretation of phase diagrams. Binary eutectic systems. Development of microstructure in eutectic alloys. Equilibrium diagrams having intermediate phases or compounds. Eutectic and peritectic reactions. Solid-phase transformations.

2. Metals
Ferrous alloys. The Iron–Iron Carbide (Fe–Fe3C) phase diagram
Development of microstructure in Iron–Carbon alloys. The influence of other alloying elements.

3. Mechanical properties and testing of materials

4. Heat treatment of steels
Microstructures. Annealing. Quenching and tempering. Tempered martensite. Surface treatments. Mechanical behaviour of Iron–Carbon alloys. Influence of heat treatment in mechanical properties

5. Ceramics
Advanced ceramics. Brittle fracture of ceramics. Stress-strain behavior
Mechanisms of plastic deformation. Mechanical properties.
6. Polymers
Thermoplastic and thermosetting polymers. Copolymers.
Polymer crystallinity. Polymer crystals. Defects in polymers. Crystallization. Melting and glass transition temperatures. Factors that influence melting and glass transition temperatures. Mechanical properties
7. Composites
Fiber-reinforced composites. The fiber phase. The matrix phase
Polymer-matrix composites. Hybrid composites. Laminar composites. Sandwich panels. Mechanical properties.

Bibliografia Obrigatória

W.D. CALLISTER, JR., JOHN WILEY AND SONS; MATERIALS SCIENCE AND ENGINEERING: AN INTRODUCTION, 7TH EDITION (2007), 2007
W. F. SMITH; PRINCÍPIOS DE CIÊNCIA E ENGENHARIA DOS MATERIAIS , MCGRAW-HILL, 3ªEDIÇÃO (1996) , 1996

Métodos de ensino e atividades de aprendizagem

Theoretical classes with the presentation of concepts and correlations between different types of materials.
Practical-Laboratory classes with problem-solving. Execution of experimental work in a laboratory environment, including material characterization tests and mechanical tests.

Tipo de avaliação

Distributed evaluation with final exam

Componentes de Avaliação

Designation	Peso (%)
Teste	40,00
Trabalho escrito	30,00
Trabalho laboratorial	30,00
Total:	100,00

Componentes de Ocupação

Designation	Tempo (Horas)
Estudo autónomo	47,00
Frequência das aulas	30,00
Trabalho de investigação	30,00
Trabalho escrito	25,00
Trabalho laboratorial	30,00
Total:	162,00

Obtenção de frequência

Final grade = 70% average grade (Test + written work) + 30% Laboratory Grade

Fórmula de cálculo da classificação final

Final grade = 70% average grade (Test + written work) + 30% Laboratory Grade

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