| Course Unit Code | 330-0520/01 |
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| Number of ECTS Credits Allocated | 4 ECTS credits |
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| Type of Course Unit * | Compulsory |
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| Level of Course Unit * | Second Cycle |
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| Year of Study * | Second Year |
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| Semester when the Course Unit is delivered | Summer Semester |
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| Mode of Delivery | Face-to-face |
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| Language of Instruction | Czech |
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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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| HAL22 | prof. Ing. Radim Halama, Ph.D. |
| BRZ021 | Ing. Tomáš Brzobohatý, Ph.D. |
| Summary |
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The subject deals with elementary theoretical and practical knowledge from region behavior of materials and constructional elements under elevated temperatures, when the creep or relaxation is situated. These are problems of classical and nuclear energetic (boilers, pipeline, generators, parts of gas engine). There are including the basis from physics of materials, testing of materials, life-time prediction, etc.
Primary, secondary and tertiary creep. Dislocation and diffusion creep models. Stress-strain relations. L-M parameters. Creep mechanism identification, Activation energy, Hoff analogy.
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| Learning Outcomes of the Course Unit |
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| To teach students the basic procedures for solving some technical problems of the continuum mechanics. To ensure understanding of such teaching problems. To learn our students to apply of theoretical knowledge in praxis. |
| Course Contents |
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The subject deals with elementary theoretical and practical knowledge from region behavior of materials and constructional elements under elevated temperatures, when the creep or relaxation is situated. These are problems of classical and nuclear energetic (boilers, pipeline, generators, parts of gas engine). There are including the basis from physics of materials, testing of materials, life-time prediction, etc.
Primary, secondary and tertiary creep. Dislocation and diffusion creep models. Stress-strain relations. L-M parameters. Creep mechanism identification, Activation energy, Hoff analogy. |
| Recommended or Required Reading |
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| Required Reading: |
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Betten, Creep Mechanics, Springer
Hetnarski, Thermal Stress - Advanced Theory and Applications |
[1] Čadek, J.: Creep kovových materiálů, Academia Praha, 1984
[2] Veles, P.: Mechanické vlastnosti kovov a ich skúšanie, ALFA, 1979
[3] Klečková, M.: Nestacionární teplotní pole a napjatost ve strojních
částech,SNTL Praha,1979
[4] Reif. P.: Teplotní napětí, skriptum ČVUT FS Praha, 1982
[5] Kuliš, Z.: Plasticita a creep, skriptum ČVUT FS Praha, 1986
[6] Fuxa, J.: Creep a teplotní namáhání – sylabus katedry pružnosti a pevnosti,
VŠB-TU Ostrava
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| Recommended Reading: |
|---|
Betten, Creep Mechanics, Springer
Hetnarski, Thermal Stress - Advanced Theory and Applications |
[1] Čadek, J.: Creep kovových materiálů, Academia Praha, 1984
[2] Veles, P.: Mechanické vlastnosti kovov a ich skúšanie, ALFA, 1979
[3] Klečková, M.: Nestacionární teplotní pole a napjatost ve strojních
částech,SNTL Praha,1979
[4] Reif. P.: Teplotní napětí, skriptum ČVUT FS Praha, 1982
[5] Kuliš, Z.: Plasticita a creep, skriptum ČVUT FS Praha, 1986
[6] Fuxa, J.: Creep a teplotní namáhání – sylabus katedry pružnosti a pevnosti,
VŠB-TU Ostrava
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| Planned learning activities and teaching methods |
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| Lectures, Tutorials |
| Assesment methods and criteria |
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| Task Title | Task Type | Maximum Number of Points
(Act. for Subtasks) | Minimum Number of Points for Task Passing |
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| Credit and Examination | Credit and Examination | 100 (100) | 51 |
| Credit | Credit | 35 | 20 |
| Examination | Examination | 65 | 16 |