Academic year 2021/2022 |
Supervisor: | doc. Ing. Vít Jan, Ph.D. | |||
Supervising institute: | ÚMVI | |||
Teaching language: | English | |||
Aims of the course unit: | ||||
The objective is to provide knowledge on the composition, structure, and treatment of materials in relation to their properties that are relevant for treatment technologies and design applications. It enables understanding the essence of the above processes and their mutual causal relations. | ||||
Learning outcomes and competences: | ||||
Technologists will be provided with the knowledge of the relations between the structure, sub-structure, and treatment properties of structural materials. Designers will learn about how to make full use of structural materials. For all materials (of both current and enhanced properties) the principles are defined for their technically and economically suitable application. | ||||
Prerequisites: | ||||
1. Structure of atom, fundamentals of crystallography 2. Basic concepts in physical chemistry (entropy, free energy, free enthalpy, phases, phase equilibria, chemical equilibria) 3. Structure of real crystals (crystal lattice defects and their properties) 4. Thermodynamics of solids 5. Diffusion, diffusion processes 6. Phases in metallic and ceramic systems. Equilibrium diagrams 7. Phase transformations 8. Deformation and fracture properties, testing of mechanical properties of structural materials |
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Course contents: | ||||
Phase transformations during the heat treatment of metals and alloys. Fundamental knowledge of structural materials (ferrous alloys and non-ferrous metals, ceramics, polymers, and composites) - their chemical composition and technological treatment in relation to their crystallographic, sub-structural, structural, and mechanical properties; degradation processes resulting from the application of these materials. Principles of selecting materials for engineering constructions. | ||||
Teaching methods and criteria: | ||||
The course is taught through lectures explaining the basic principles and theory of the discipline. Teaching is suplemented by practical laboratory work. | ||||
Assesment methods and criteria linked to learning outcomes: | ||||
Examination. The examination consists of written and oral part. In the written part, students answer four questions related to topics dealt with in the course of the semester. In the oral part, students answer questions resulting from the written part as well as examiner's additional questions. | ||||
Controlled participation in lessons: | ||||
Awarding the course. Participation in practices is mandatory, must be properly excused absence. Unit credit is conditional on having participated in all exercises and worked out the reports from exercises in keeping with the teacher's instructions. Absence from exercises must be accounted for. Students who have missed an exercise will be given an extra assignment. They will prove in the form of a written report that they have mastered the given topic. | ||||
Type of course unit: | ||||
Lecture | 13 × 2 hrs. | optionally | ||
Laboratory exercise | 13 × 2 hrs. | compulsory | ||
Course curriculum: | ||||
Lecture | 1. Fundamentals of the metallurgy of iron and steel 2. Accompanying and additive elements in alloys of iron and carbon 3. Phase transformation in the heat treatment of ferrous alloys 4. Heat treatment procedures 5. Low-carbon structural steels for welded structures, case-hardening steel, deep drawing steel, structural steels for heat treatment, 6. Steels resistant to corrosion, heat, creep, 7. Tool steels and alloys 8. Cast irons 9. Non-ferrous metals and alloys I - Al, Mg, Ti 10. Structural metals and alloys II - Cu, Ni, Co 11. Structural ceramic materials 12. Structural polymers 13. Composite materials 14. Principles of selecting structural materials |
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Laboratory exercise | 1.Introductory exercises. Organizational matters, training, work safety 2. Standard marking the steels and cast irons, 3. Structure and properties of iron alloys. 4. Austenitizace, diagrams. of the IRA, ARA 5. Basic types of thermal processing 6. Chemical-thermal treatment. 7. Low-carbon steel. 8. Stainless steel and heat-resistant. 9. Tool steel. 10. Graphitic cast iron. 11. Non-ferrous metals I-solders and Al alloys 12. Non-ferrous metals II-Cu alloys 13. Polymers. |
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Literature - fundamental: | ||||
1. Ashby, F.M., Jones, D.R.H. Engineering Materials I, II, Pergamon Press, Ltd., England 1989 | ||||
2. Ohring M.: Engineering Materials Science, Academie Press, New York, 1995 | ||||
3. Callister, W.D., Jr. Materials Science and Engineering, John Willey & Sons, Inc; New York, 1994 | ||||
Literature - recommended: | ||||
1. Ptáček L. et al. Materials science II (in Czech), CERM, Brno 2002 | ||||
2. Pluhař, J. et al. Material science (in Czech), SNTL, Praha, 1989 | ||||
3. Pluhař, J. - Koritta J. Engineering materials (in Czech), SNTL/ALFA, Praha, 1977 |
The study programmes with the given course: | |||||||||
Programme | Study form | Branch | Spec. | Final classification | Course-unit credits | Obligation | Level | Year | Semester |
B-STI-A | full-time study | --- no specialisation | -- | Cr,Ex | 5 | Compulsory | 1 | 2 | W |
N-ENG-A | full-time study | --- no specialisation | -- | Cr,Ex | 5 | Compulsory | 2 | 2 | W |
Faculty of Mechanical Engineering
Brno University of Technology
Technická 2896/2
616 69 Brno
Czech Republic
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