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ECTS Course Overview



Technical Vibrations

* Exchange students do not have to consider this information when selecting suitable courses for an exchange stay.

Course Unit Code330-0304/03
Number of ECTS Credits Allocated5 ECTS credits
Type of Course Unit *Choice-compulsory
Level of Course Unit *First Cycle
Year of Study *
Semester when the Course Unit is deliveredWinter Semester
Mode of DeliveryFace-to-face
Language of InstructionEnglish
Prerequisites and Co-Requisites Course succeeds to compulsory courses of previous semester
Name of Lecturer(s)Personal IDName
POD10doc. Ing. Jiří Podešva, Ph.D.
Summary
Extending knowledge about vibration of one degree-of-freedom linear systems,
vibrations excited by rotating mass, transfer of force to subsurface, forced
vibrations excited by periodic force and by force of general time behaviour.
Longitudinal and torsion vibration of linear multi degree-of-freedom systems,
bending vibration of linear multi degree-of-freedom systems, critical speed of
shafts. Non-linear one degree-of-freedom systems vibration.
Learning Outcomes of the Course Unit
To teach the students the basic theory of linear vibration with one and more degrees of freedom. To teach the basics of non-linear vibration of mechanical systems. To be able to apply the retrieved knowledge to solve the technical problems.
Course Contents
The natural longitudinal vibration, undamped and damped, linear, with 1 degree of freedom (DOF).
The spring assemblies, serial and parallel.
Bending stiffness, bending vibration.
The forced vibration, undamped and damped.
Constant force, harmonically changing force.
The steady state solution. The amplitude and phase diagram.
The vibration due to centrifugal force.
The force transmision into the ground.
Rotational vibration, natural and forced, torsional stiffness.

Exam questions
1. The natural undamped vibration, parameters, equation of motion
2. The natural undamped vibration, time function, parameters
3. The natural damped vibration, parameters, equation of motion
4. The natural damped vibration, time function, parameters
5. The spring assemblies
6. Bending stiffness, bending vibration
7. The forced vibration, parameters, equation of motion
8. The forced vibration, time function, parameters
9. The forced vibration, amplitude characteristic
10. The forced vibration due to centrifugal force
11. Rotational vibration, natural
12. Rotational vibration, forced
13. Torsional stiffness
Recommended or Required Reading
Required Reading:
[1] GÉRADIN, M. a RIXEN, D.. Mechanical vibrations: theory and applications to structural dynamics. Chichester: Wiley, 1994. ISBN 0-471-93927-7.

[2] https://www.fs.vsb.cz/330/en/technical-vibration/
[1] BROUSIL, J., SLAVÍK, J., ZEMAN, V. Dynamika. Praha: SNTL/ALFA,1989. 328 s.

[2] ONDROUCH, J a PODEŠVA, J. Technické kmitání, Ostrava: VŠB - Technická univerzita Ostrava, 2012. Dostupný z https://www.fs.vsb.cz/export/sites/fs/330/.content/files/Podesva_kmitani.pdf

[3] GÉRADIN, M. a RIXEN, D.. Mechanical vibrations: theory and applications to structural dynamics. Chichester: Wiley, 1994. ISBN 0-471-93927-7.
Recommended Reading:
https://www.fs.vsb.cz/330/en/technical-vibration/
[1] JULIŠ, K,- BREPTA, R. Mechanika II. Díl Dynamika. Praha: SNTL , 1987. 685 s.

[2] BRÁT, V., STEJSKAL, V. a VOTÍPKA, F.. Základy dynamiky strojů a konstrukcí. Vyd. 3. Praha: České vysoké učení technické, 1982.
Planned learning activities and teaching methods
Lectures, Tutorials
Assesment methods and criteria
Tasks are not Defined