| Course title | Elasticity and Rigidity |
|---|---|
| Course code | USE/KX018 |
| Organizational form of instruction | Lecture |
| Level of course | Bachelor |
| Year of study | 2 |
| Semester | Winter |
| Number of ECTS credits | 6 |
| Language of instruction | Czech |
| Status of course | Compulsory |
| Form of instruction | unspecified |
| Work placements | unspecified |
| Recommended optional programme components | None |
| Lecturer(s) |
|---|
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| Course content |
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Contents: 1. Basic terms from mechanics of yielding body. 2. Traction and pressure of rods. Rod systems. 3. Bending straight and indirect beams statically defined supported. 4. Bending beams and frames static blankly supported. 5. Cutting. 6. Torsion direct beams. 7. Compressive vessel. 8. Compound tension. Rigidity hypotheses. 9. Dimensioning of mechanical parts. Loading of mechanical parts. 10. Dimensioning of quazistationary loaded part. 11. Dimensioning of dynamical loaded part. 12. Stability of mechanical part. Buckling of slim rods. 13. Principle of final element method (FEM).
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| Learning activities and teaching methods |
| unspecified |
| Learning outcomes |
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Elasticity and rigidity deal with inner force and deformations in mechanical parts and construction due to outer static or dynamic load and offer so basic information to their dimensioning and classification their serviceability and service life. Students will get knowledges and skills to rigidity and deformation analysis of mechanical part.
Prerequisites and co-requisites Knowledge to the extent necessary to solve problems in other subjects of the field, the ability to apply knowledge in the design and construction of machines. Students will gain technical imagination, connections and connections in the solution of machine parts and structures. After graduation, they can statically and dynamically dimension the basic shapes of machine units and parts. |
| Prerequisites |
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unspecified
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| Assessment methods and criteria |
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unspecified
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| Recommended literature |
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| Study plans that include the course |
| Faculty | Study plan (Version) | Category of Branch/Specialization | Recommended semester | |
|---|---|---|---|---|
| Faculty: Faculty of Mechanical Engineering | Study plan (Version): Materials and Technologies in Transport (16) | Category: Mechanical engineering and mechanical production | 2 | Recommended year of study:2, Recommended semester: Winter |
| Faculty: Faculty of Mechanical Engineering | Study plan (Version): Materials and Technologies in Transport (11) | Category: Mechanical engineering and mechanical production | 2 | Recommended year of study:2, Recommended semester: Winter |
| Faculty: Faculty of Mechanical Engineering | Study plan (Version): Materials and Technologies in Transport (17) | Category: Mechanical engineering and mechanical production | 2 | Recommended year of study:2, Recommended semester: Winter |
| Faculty: Faculty of Mechanical Engineering | Study plan (Version): Production Management (11) | Category: Mechanical engineering and mechanical production | 2 | Recommended year of study:2, Recommended semester: Winter |
| Faculty: Faculty of Mechanical Engineering | Study plan (Version): Production Management (16) | Category: Mechanical engineering and mechanical production | 2 | Recommended year of study:2, Recommended semester: Winter |
| Faculty: Faculty of Mechanical Engineering | Study plan (Version): Production Management (17) | Category: Mechanical engineering and mechanical production | 2 | Recommended year of study:2, Recommended semester: Winter |
| Faculty: Faculty of Mechanical Engineering | Study plan (Version): Energetics - Heat Industry (17) | Category: Special and interdisciplinary fields | 2 | Recommended year of study:2, Recommended semester: Winter |