Lecturer(s)
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Janáčová Dagmar, prof. Ing. CSc.
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Course content
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- Heat transfer, sharing mechanisms, basic concepts and laws. - Non-stationary heat conduction in the plate, cylinder and sphere-shaped bodies. Fourier-Kirchhoff differential equation of heat conduction, initial and boundary conditions - analytical solution by Fourier separation of variables. Technical significance. - Solution of the temperature field in a multilayer board. - Solution of an asymmetric temperature field in a plane plate. - Non-stationary heat balance of selected problems, mathematical description, solution by Laplace transform. - Simulation of tasks using SW Mathematica and COMSOL Multiphysics.
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Learning activities and teaching methods
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Lecturing, Individual work of students
- Participation in classes
- 56 hours per semester
- Home preparation for classes
- 20 hours per semester
- Preparation for examination
- 50 hours per semester
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prerequisite |
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Knowledge |
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Knowledge of process engineering from the master's degree program. |
Knowledge of process engineering from the master's degree program. |
learning outcomes |
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The student has knowledge about the sharing of heat, mass and energy. |
The student has knowledge about the sharing of heat, mass and energy. |
Skills |
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The student is able to perform more demanding balance calculations related to the dynamic behavior of systems. |
The student is able to perform more demanding balance calculations related to the dynamic behavior of systems. |
The student orients himself in the necessary literature and is able to find the necessary thermodynamic data and thus successfully implement the necessary calculations to minimize energy consumption in production technologies while maintaining the required properties of the product. |
The student orients himself in the necessary literature and is able to find the necessary thermodynamic data and thus successfully implement the necessary calculations to minimize energy consumption in production technologies while maintaining the required properties of the product. |
teaching methods |
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Knowledge |
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Individual work of students |
Individual work of students |
Methods for working with texts (Textbook, book) |
Methods for working with texts (Textbook, book) |
Lecturing |
Lecturing |
Skills |
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Individual work of students |
Individual work of students |
Practice exercises |
Practice exercises |
assessment methods |
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Knowledge |
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Oral examination |
Oral examination |
Analysis of seminar paper |
Analysis of seminar paper |
Grade (Using a grade system) |
Grade (Using a grade system) |
Recommended literature
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Kurz Procesní inženýrství III. Moodle, dostupné na http://vyuka.fai.utb.cz/course/view.php?id=126, vstupní heslo: ping3.
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Bejan, A., Kraus, A.D. Heat Transfer Handbook. John Wiley & Sons, 2003. ISBN 978-0-471-39015-2.
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BIRD, R.B., Steward, W.E., Lightfoot, E.N. Transport Phenomena.. John Wiley & Sons, 2007. ISBN 0-470-11539-4.
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Carslaw, H.S., Jaeger, J.C. Conduction of Heat in Solids. Oxford: Clarendon Press, 2000. ISBN 0-19-853368-3.
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DRÁBEK, D., KLEPÁČ, J. Procesné strojníctvo II, STU Bratislava, 2000. ISBN 80-227-1340-6.
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Janáčová, D., Charvátová,H., Kolomazník, K., Blaha, A. Procesní inženýrství : transportní, fyzikální a termodynamická data. Univerzita Tomáše Bati ve Zlíně, 2011. ISBN 978-80-7318-997-6.
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JANOTKOVÁ, E., PAVELEK, M. Termomechanika, FSI VUT Brno, 2003.
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Kalpakjan, S. Manufacturing Engineering and Technology. Addison-Wesley Publishing Company, 1989. ISBN 0-201-53846-6.
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KOLAT, P. Přenos tepla a hmoty, FS, VŠB-TU Ostrava, 2001.
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Ozisik, N. Heat Transfer. McGraw-Hill Book Company, 1985.
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Serth, R.W., Lestina, T.G. Process Heat Transfer: Principles, Applications and Rules of Thumb. ISBN 9780123977922.
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Šesták, Jiří. Přenos hybnosti, tepla a hmoty. 2. vyd. Praha : ČVUT, 1998. ISBN 800101715X.
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