Course Unit Code | 653-3002/03 |
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Number of ECTS Credits Allocated | 6 ECTS credits |
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Type of Course Unit * | Optional |
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Level of Course Unit * | Second Cycle |
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Year of Study * | |
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Semester when the Course Unit is delivered | Winter, Summer Semester |
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Mode of Delivery | Face-to-face |
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Language of Instruction | English |
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Prerequisites and Co-Requisites | Course succeeds to compulsory courses of previous semester |
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Name of Lecturer(s) | Personal ID | Name |
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| LOS35 | doc. Dr. Ing. Monika Losertová |
Summary |
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Subject takes up basic knowledge of material science and upgrades knowledge of materials used in present-day industries including different physical, mechanical, thermal and other properties. Structure effects (precipitation, recristallization, recovery, deformation, etc.) in selected materials are mentioned in the context of the mechanical behavior (creep, deformation, superplacticity, superelasticity, embrittlement) and applications for different types of materials: superalloys, intermetallics, metal matrix composites, metallic glasses, metallic foams, functionnaly graded materials, shape memory alloys, etc. Knowledge enables to students acquiring survey of trends of new material development and of used present-day materials. |
Learning Outcomes of the Course Unit |
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Student should be able to do the following:
- explain relationships between structure and basic properties of advanced materials
- classify and make an overview of basic properties of structural, electromagnetic, superconducting, biocompatible, composite and other materials in various industries
- formulate advantages and disadvantages of applications of metallic materials
- recommend suitable thermo-mechanical treatment for modification of structures and properties of materials
- compare and select individual types of materials according to selected properties for specific applications
- optimize material and technological parameters of production
- analyse and evaluate influence of impurities on service properties of materials
- apply the findings at solution of technical problems |
Course Contents |
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1. Overview of materials, their properties and application.
2. Copper based materials. Cu-Ni based alloys. Phase transformation in Cu alloys, effect on the properties of the alloys.
3. Nickel based alloys. Alloys with special magnetic and other physical properties. Structure and phase features in the context of application.
4. Superalloys on the base of Fe-Ni, Co or Ni. Physical and metallurgical features, mechanical and corrosion properties, heat treatment, phase stability. Application.
5. Titanium based alloys. Classification (alpha, beta, alpha+beta). Phase transformations in Ti alloys. Precipitation reactions and deformation behaviour. Effect of heat treatment on microstructure features of Ti alloys. Application.
6. Intermetallics. Structure. Phase stability. Antiphase boundaries and domains. Mechanical, electromagnetic, corrosion, thermal and superconductive properties. Classification of intermetallic alloys, overview, structures, properties and application. IMC based hydrides, properties and application.
7. Shape memory alloys. Fundamentals of shape memory effect. Phase transformations. Structure and microstructure. Thermoelastic or stress induced martensite. Superelasticity. Examples of alloys, application.
8. Functionnaly graded materials. Fundamentals, structure, properties, examples, application.
9. Metal matrix composites (MMC). Fundamentals of composite effect. Mechanisms of strengthening. Classification of composites according to reinforcement, structures or matrix composition. Material features. Application.
10. Metallic glasses. Physical and metallurgical features. Glass forming ability. Stability and crystallisation. Advantages and limitations for using. Examples of materials, properties and application.
11. Metallic foams.Classification and microstructures, metallurgical properties, advantages and application.
12. Biocompatible materials. Biocompatibility. Classification of materials. Properties and application. |
Recommended or Required Reading |
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Required Reading: |
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LOSERTOVÁ, M. Advanced Materials. Ostrava: VŠB-TU Ostrava, 2012.
SMALLMAN, R.E. a A.H.W NGAN. Physical metallurgy and advanced materials. 7th ed. Oxford: Elsevier Butterworth-Heinemann, 2007. ISBN 978-0-7506-6906-1.
REED, R. C. The Superalloys. Fundamentals and Applications. Cambridge University Press The Edinburgh Building, Cambridge cb2 2ru, UK. 2006. pp. 372. ISBN-13 978-0-521-85904-2 |
LOSERTOVÁ, M. Progresivní materiály. Ostrava: VŠB-TU Ostrava, 2012. Online na: http://www.person.vsb.cz/archivcd/FMMI/PGM/index.htm.
SMALLMAN, R.E. a A.H.W NGAN. Physical metallurgy and advanced materials. 7th ed. Oxford: Elsevier Butterworth-Heinemann, 2007. ISBN 978-0-7506-6906-1.
FIALA, J., V. MENTL a P. ŠUTTA. Struktura a vlastnosti materiálů. Praha: Academia, 2003. ISBN 80-200-1223-0. |
Recommended Reading: |
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VANDER VOORT, G. F., ed. ASM Handbook: Metallography and Microstructure. Volume 9. Ohio: ASM International. 2004. ISBN 978-0-87170-706-2.
DONACHIE, M.J. a S.J. DONACHIE. Superalloys: a technical guide. 2nd ed. Materials Park: ASM International, 2002. ISBN 0-87170-749-7.
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VANDER VOORT, G. F., ed. ASM Handbook: Metallography and Microstructure. Volume 9. Ohio: ASM International. 2004. ISBN 978-0-87170-706-2.
REED, R. C. The Superalloys. Fundamentals and Applications. Cambridge University Press The Edinburgh Building, Cambridge cb2 2ru, UK. 2006. pp. 372. ISBN-13 978-0-521-85904-2 |
Planned learning activities and teaching methods |
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Lectures, Seminars, Individual consultations, Tutorials, Project work |
Assesment methods and criteria |
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Tasks are not Defined |