Course Unit Code | 338-0322/01 |
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Number of ECTS Credits Allocated | 5 ECTS credits |
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Type of Course Unit * | Compulsory |
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Level of Course Unit * | First 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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| KOZ30 | prof. RNDr. Milada Kozubková, CSc. |
| KAD15 | doc. Ing. Zdeněk Kadlec, Ph.D. |
| DRA10 | doc. Ing. Sylva Drábková, Ph.D. |
| JAN13 | Ing. Radim Janalík, CSc. |
| DVO31 | Ing. Lukáš Dvořák, Ph.D. |
Summary |
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In this course students learn the basic principles of two disciplines: fluid mechanics and thermodynamics.
Fluid mechanics deals with the balance of forces in liquids at rest and in motion.
Basic laws of mechanics are applied, i.e. the conditions of force balance and momentum balance, conservation of mass and energy.
Thermomechanics is a basic science, which includes thermodynamics of gases and heat transfer. It has a number of practical applications in various disciplines and in everyday life. |
Learning Outcomes of the Course Unit |
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In this course students learn the basic principles of two disciplines: fluid mechanics and thermodynamics. They will be based on knowledge gained in general mechanics, which can be applied to discover the laws of the continuum. To understand the curriculum they implement a simple experimental task. They will be able to solve practical problems of thermodynamics and fluid mechanics and will get familiar with solving complex engineering problems.
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Course Contents |
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1. Pressure in a liquid at rest, Euler equation of hydrostatics and its application. Pascal's law. Pressure force on planar and curved surfaces. Fluids in relative rest.
2. Ideal fluid flow. Continuity equation. Euler equation of hydrodynamics. Bernoulli equation and its appluication. Terms of use. Measurement of liquid velocity and pressure in pipes.
3. Viscous fluid flow. Navier -Stoces equation. Bernoulli equation for real fluid. Hydraulic friction and local losses.
4. Hydraulic calculation of pipes. Hydraulic system, centrifugal pump, pump operation in hydraulic system. Uniform flow through the open channel.
5. Discharge from containers through hole and orifice, emptying of containers, weirs.
6. Unsteady flow in a pipe. Extended Bernoulli equation. Hydraulic shock.
7. Momentum equation and its application. Flow over bodies. Physical similarity in hydromechanics and its applications.
8. Reversible changes in ideal gas. Ideal gas law.
9. The first law of thermodynamics for a closed system. Heat cycles. Heat added to or removed from a body, work of expansion and compression.
10. The second law of thermodynamics. Determining the change in entropy of the basic reversible processes. Direct and reverse heat cycles. Carnot cycle.entropy of the basic reversible processes. Direct and reverse heat cycles. Carnot's cycle. 11. Comparison of explosive motor cycles, mixed and equal-combustion turbines. Determination of thermal efficiency and work done. Ideal and real single-stage compressor. Multistage compression.
12. Real gas, heat quantities, equation of state. A simplified calculation for real gas, assumptions, significance. Gas mixture.
13. Steam, basic concepts. Reversible changes of steam and their representation in the diagram, p-v and T-s. A simple ideal steam cycle T-s diagram. Steam Rankine-Claussian cycle. Humidity. Enthalpy of humid air and its thermal diagram
14. Basic types of thermal energy transmission. Stationary conduction and heat transfer with unlimited wall planar and cylindrical, simple and composite. Heat exchangers, the basis of heat calculation of recuperative heat exchangers. |
Recommended or Required Reading |
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Required Reading: |
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SHAUGHNESSY, E. J., KATZ, I. M., SCHAFFER, J. P.: Introduction to Fluid Mechanics. New York: Oxford University Press. 2005. ISBN-13: 978-0195154511. ISBN-10: 0195154517.
MORAN, M.J.; SHAPIRO, H. N.: Fundamental of Engineering Thermodynamics. 2.vyd. New York: John Wiey & Sons, Inc., 1992. ISBN 0471076813.
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DRÁBKOVÁ, S. A KOL.: Mechanika tekutin, VŠB-TU Ostrava, 2007, 260 s. Dostupné na https://www.fs.vsb.cz/338/cs/studium/mechanika-tekutin/
DRÁBKOVÁ, S., KOZUBKOVÁ, M.: Cvičení z Mechaniky tekutin. Sbírka příkladů. VŠB-TU Ostrava 2004, dostupné na https://www.fs.vsb.cz/338/cs/studium/mechanika-tekutin/
Návody pro laboratorní měření dostupné na https://www.fs.vsb.cz/338/cs/studium/mechanika-tekutin/
HLOUŠEK, J. A KOL.: Termomechanika. 1.vyd. Brno: VUT, 1992, 297 s. ISBN 80-214-0387-X.
KADLEC, Z.: Termomechanika, návody do cvičení. 1.vyd. Ostrava: VŠB-TU,2002. 97 s.
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Recommended Reading: |
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MUNSON, B. R., YOUNG, D. F., OKIISHI, T.: Fundamentals of Fluid Mechanics. March: Wiley Text Books, 2002. ISBN 047144250X
FOX, R.W., MC DONALD, A.T.: Introduction to Fluid Mechanics. J. Wiley & sons, New York, 1994
ASWATHA NARAYANA, P.A., SEETHARAMU, K.N.: Engineering Fluid Mechanics. Alpha Asience International Ltd., Harrow, U.K., 2005
JÍLEK, M.: Thermomechanics, 3.vyd. Praha: ČVUT, 2011,176 s. ISBN 978-80-01-04750-7
JÍLEK, M.: Exercises and Labs in Thermomechanics, 3.vyd. Praha: ČVUT, 2012,138 s. ISBN 978-80-01-05086-6 |
NOSKIEVIČ, J. A KOL.: Mechanika tekutin. Praha: SNTL, 1987, 354 str.
NOŽIČKA, J.: Termomechanika. 1.vyd. Praha: ČVUT,1998,179 s. ISBN 80-01-01836-9 |
Planned learning activities and teaching methods |
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Lectures, Tutorials, Experimental work in labs |
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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Exercises evaluation and Examination | Credit and Examination | 100 (100) | 51 |
Exercises evaluation | Credit | 30 | 20 |
Examination | Examination | 70 | 21 |