Course detail
Thermal Turbomachines
FSI-9TETAcad. year: 2023/2024
This level is focuses on study effects and construction possibility for the best efficiency of steam turbines, gas turbines and turbocompressors. This study is in context with construction, projection, operational, economical and ecological impacts. During the study are students making acquaintance of development in design of steam turbines, gas turbines and turbocompressors, development results and views into the future.
Language of instruction
Czech
Mode of study
Not applicable.
Guarantor
Department
Entry knowledge
LLS, TT1, TT2
Rules for evaluation and completion of the course
Final exam by oral interview
Not
Not
Aims
Objective of the course in terms of learning outcomes and competences The aim of the subject is to acquaint students with analytical calculation and conceptual design with detailed design solution of large and small thermal turbines
Upon completion of the course the student is able to analyze complex thermodynamic calculations in the flow channel of the steam turbine, including its optimization
Upon completion of the course the student is able to analyze complex thermodynamic calculations in the flow channel of the steam turbine, including its optimization
Study aids
Not applicable.
Prerequisites and corequisites
Not applicable.
Basic literature
Dejč, M. E.: Technická dynamika plynů. SNTL, Praha 1967, s. 659
Dixon, S. L.: Fluid Mechanics, Thermodynamics of Turbomachinery. Pergamon Pres 1966, p. 213
Kadrnožka, J.: Tepelné elektrárny a teplárny. SNTL, Praha 1984, s. 607
Kadrnožka, J., Tepelné turbiny a turbokompresory I, CERM, Brno 2004
Dixon, S. L.: Fluid Mechanics, Thermodynamics of Turbomachinery. Pergamon Pres 1966, p. 213
Kadrnožka, J.: Tepelné elektrárny a teplárny. SNTL, Praha 1984, s. 607
Kadrnožka, J., Tepelné turbiny a turbokompresory I, CERM, Brno 2004
Recommended reading
Cohen, N.-Rogus, G.F.C.-Saravanomuttoo, H.I.H: Gas Turbin Theory. Adisson Wesley Longman 1998, p.442
Lakshminaragana, B._: Fluid Dynamics and Heat Transfer of Turbomachinery. John Wiley 1996, p. 809
Ščegljajev, A.V.: Parní turbíny 1 a 2. SNTL Praha 1989, s. 368+395
Lakshminaragana, B._: Fluid Dynamics and Heat Transfer of Turbomachinery. John Wiley 1996, p. 809
Ščegljajev, A.V.: Parní turbíny 1 a 2. SNTL Praha 1989, s. 368+395
Classification of course in study plans
Type of course unit
Lecture
20 hod., optionally
Teacher / Lecturer
Syllabus
1. Steam turbines and gas turbines cycles,
2. Turbines for combined production of electricity and heat
3. Thermodynamic and transport properties of working fluids
4. Flow in turbine machinery
5. CFD simulation of flow in turbine machinery
6. Expansion and compression in turbine machinery
7. Heat transfer in turbine machinery, energy losses and their reducing
8. Theory of turbine machinery degree (axial, radial, diagonal)
9. Similarity of turbine machinery
10. Space flow in turbine machinery
11. Necks of turbine machinery
12. Multistage turbine machinery
13. Construction of the main parts of turbine machinery, shaft seal in turbine machinery
2. Turbines for combined production of electricity and heat
3. Thermodynamic and transport properties of working fluids
4. Flow in turbine machinery
5. CFD simulation of flow in turbine machinery
6. Expansion and compression in turbine machinery
7. Heat transfer in turbine machinery, energy losses and their reducing
8. Theory of turbine machinery degree (axial, radial, diagonal)
9. Similarity of turbine machinery
10. Space flow in turbine machinery
11. Necks of turbine machinery
12. Multistage turbine machinery
13. Construction of the main parts of turbine machinery, shaft seal in turbine machinery