CTU FEE Moodle
Machinery and Structures of Power Plants
B232 - Summer 23/24
This is a grouped Moodle course. It consists of several separate courses that share learning materials, assignments, tests etc. Below you can see information about the individual courses that make up this Moodle course.
Machinery and Structures of Power Plants - B1M14SSE
Main course
Credits | 5 |
Semesters | Winter |
Completion | Assessment + Examination |
Language of teaching | Czech |
Extent of teaching | 2P+2C |
Annotation
The aim of the course is to acquaint students with forms of energy transformation in power plants, describing the function of power facilities, their structure, properties and characteristics.
Study targets
No data.
Course outlines
1.Balance of energy conversion chains in power engineering
2.Thermodynamics of real gases and vapours, computational charts and programs
3.Thermodynamic power cycles, possibility of efficiency increasing
4.Steam turbines for classical and nuclear power stations, structures, characteristics, function
5.Combustion turbines and microturbines, structures, characteristics, function
6.Heat exchangers and steam generators
7.Hydrodynamics of real turbines
8.Conduit (pipelines) systems
9.Models and function of boiler (steam generator)
10.Combined gas-vapour power cycles
11.Turbines for hydraulic power stations, characteristics, function for different heads of water and installed powers
12.Characteristics of auxiliary equipment (hydraulic pumps, valves, hydraulic servomechanisms)
13.Machinery components of disperse sources
14.Modern combustion systems and ecology
2.Thermodynamics of real gases and vapours, computational charts and programs
3.Thermodynamic power cycles, possibility of efficiency increasing
4.Steam turbines for classical and nuclear power stations, structures, characteristics, function
5.Combustion turbines and microturbines, structures, characteristics, function
6.Heat exchangers and steam generators
7.Hydrodynamics of real turbines
8.Conduit (pipelines) systems
9.Models and function of boiler (steam generator)
10.Combined gas-vapour power cycles
11.Turbines for hydraulic power stations, characteristics, function for different heads of water and installed powers
12.Characteristics of auxiliary equipment (hydraulic pumps, valves, hydraulic servomechanisms)
13.Machinery components of disperse sources
14.Modern combustion systems and ecology
Exercises outlines
1.Heat transfer and work in thermal processes
2.Processes in water steam, application of thermal diagrams
3.Qualitative evaluation of most important energetic transformation
4.Work , power and thermal efficiency of steam turbines cycles, regulation of the power
5.Work , power and thermal efficiency of gas turbines
6.Heat exchanger behaviour in thermodynamic power cycles
7.Calculation of velocities and pressures in hydraulic systems with losses
8.Characteristics of hydraulic systems for fluid and gas transport
9.Basic types boilers behaviour, regulation of the power
10.Calculation of work, power and thermal efficiency of gas-vapour power cycles
11.Energy balance of basic types water turbines, cavitation
12.Operational point of the pump, hydraulic system regulation, energy saving due to speed regulation
13.Basic calculation of wind engine
14.Clean coal technology, balance of gas-vapour power cycle Vřesová
2.Processes in water steam, application of thermal diagrams
3.Qualitative evaluation of most important energetic transformation
4.Work , power and thermal efficiency of steam turbines cycles, regulation of the power
5.Work , power and thermal efficiency of gas turbines
6.Heat exchanger behaviour in thermodynamic power cycles
7.Calculation of velocities and pressures in hydraulic systems with losses
8.Characteristics of hydraulic systems for fluid and gas transport
9.Basic types boilers behaviour, regulation of the power
10.Calculation of work, power and thermal efficiency of gas-vapour power cycles
11.Energy balance of basic types water turbines, cavitation
12.Operational point of the pump, hydraulic system regulation, energy saving due to speed regulation
13.Basic calculation of wind engine
14.Clean coal technology, balance of gas-vapour power cycle Vřesová
Literature
1. Moran, M.,J., Shapiro, H.,N.: Fundamentals of Engineering Thermodynamics. Wiley, 2008.
2. Cengel,Z., Boles, M.,A.: Thermodynamics An Engineering Approach. McGraw-Hill, 2005.
3. Aungier, R.,H.: Turbine Aerodynamics. ASME, 2006.
2. Cengel,Z., Boles, M.,A.: Thermodynamics An Engineering Approach. McGraw-Hill, 2005.
3. Aungier, R.,H.: Turbine Aerodynamics. ASME, 2006.
Requirements
No data.
Machinery and Structures of Power Plants - BD1M14SSE
Credits | 5 |
Semesters | Winter |
Completion | Assessment + Examination |
Language of teaching | Czech |
Extent of teaching | 14KP+6KC |
Annotation
The aim of the course is to acquaint students with forms of energy transformation in power plants, describing the function of power facilities, their structure, properties and characteristics.
Study targets
No data.
Course outlines
1.Balance of energy conversion chains in power engineering
2.Thermodynamics of real gases and vapours, computational charts and programs
3.Thermodynamic power cycles, possibility of efficiency increasing
4.Steam turbines for classical and nuclear power stations, structures, characteristics, function
5.Combustion turbines and microturbines, structures, characteristics, function
6.Heat exchangers and steam generators
7.Hydrodynamics of real turbines
8.Conduit (pipelines) systems
9.Models and function of boiler (steam generator)
10.Combined gas-vapour power cycles
11.Turbines for hydraulic power stations, characteristics, function for different heads of water and installed powers
12.Characteristics of auxiliary equipment (hydraulic pumps, valves, hydraulic servomechanisms)
13.Machinery components of disperse sources
14.Modern combustion systems and ecology
2.Thermodynamics of real gases and vapours, computational charts and programs
3.Thermodynamic power cycles, possibility of efficiency increasing
4.Steam turbines for classical and nuclear power stations, structures, characteristics, function
5.Combustion turbines and microturbines, structures, characteristics, function
6.Heat exchangers and steam generators
7.Hydrodynamics of real turbines
8.Conduit (pipelines) systems
9.Models and function of boiler (steam generator)
10.Combined gas-vapour power cycles
11.Turbines for hydraulic power stations, characteristics, function for different heads of water and installed powers
12.Characteristics of auxiliary equipment (hydraulic pumps, valves, hydraulic servomechanisms)
13.Machinery components of disperse sources
14.Modern combustion systems and ecology
Exercises outlines
1.Heat transfer and work in thermal processes
2.Processes in water steam, application of thermal diagrams
3.Qualitative evaluation of most important energetic transformation
4.Work , power and thermal efficiency of steam turbines cycles, regulation of the power
5.Work , power and thermal efficiency of gas turbines
6.Heat exchanger behaviour in thermodynamic power cycles
7.Calculation of velocities and pressures in hydraulic systems with losses
8.Characteristics of hydraulic systems for fluid and gas transport
9.Basic types boilers behaviour, regulation of the power
10.Calculation of work, power and thermal efficiency of gas-vapour power cycles
11.Energy balance of basic types water turbines, cavitation
12.Operational point of the pump, hydraulic system regulation, energy saving due to speed regulation
13.Basic calculation of wind engine
14.Clean coal technology, balance of gas-vapour power cycle Vřesová
2.Processes in water steam, application of thermal diagrams
3.Qualitative evaluation of most important energetic transformation
4.Work , power and thermal efficiency of steam turbines cycles, regulation of the power
5.Work , power and thermal efficiency of gas turbines
6.Heat exchanger behaviour in thermodynamic power cycles
7.Calculation of velocities and pressures in hydraulic systems with losses
8.Characteristics of hydraulic systems for fluid and gas transport
9.Basic types boilers behaviour, regulation of the power
10.Calculation of work, power and thermal efficiency of gas-vapour power cycles
11.Energy balance of basic types water turbines, cavitation
12.Operational point of the pump, hydraulic system regulation, energy saving due to speed regulation
13.Basic calculation of wind engine
14.Clean coal technology, balance of gas-vapour power cycle Vřesová
Literature
1. Moran, M.,J., Shapiro, H.,N.: Fundamentals of Engineering Thermodynamics. Wiley, 2008.
2. Cengel,Z., Boles, M.,A.: Thermodynamics An Engineering Approach. McGraw-Hill, 2005.
3. Aungier, R.,H.: Turbine Aerodynamics. ASME, 2006.
2. Cengel,Z., Boles, M.,A.: Thermodynamics An Engineering Approach. McGraw-Hill, 2005.
3. Aungier, R.,H.: Turbine Aerodynamics. ASME, 2006.
Requirements
No data.
Power Machine Equipment - B1M14ESZ
Credits | 5 |
Semesters | Winter |
Completion | Assessment + Examination |
Language of teaching | Czech |
Extent of teaching | 2P+2C |
Annotation
The course deals with the analysis of the basic functions and characteristics of machinery used in the energy sector, introduces students to quantitative and qualitative energy balances of these devices to an extent, allowing to obtain the technical basis for the economic evaluation, as well as operating system optimization. It also deals with the analysis of the impact of failures of machine elements of the power system to the technical indicators and economical operation and performance of the most important methods of control machinery of power plants in terms of their operational optimization.
Study targets
No data.
Course outlines
1. The basic types of cycles used in power engineering, energy balance, determine the basic operating parameters.
2. Qualitative evaluation of basic heat technical processes, thermal cycles in the energy sector.
3. Energy intensity in the transportation of liquids and gases, the working point, the energy regulatory assessment methods.
4. The steam turbine, basic principal, basic balance and output characteristics of the basic types of steam turbines.
5. Ways power control condensation and heat circulation. Turbine with controlled steam draw.
6. Condensation, cooling circuits, analysis of operating failures of condensation systems. Impact on the economy of operation of the unit.
7. Synergies and operational linkages and regulatory machinery in the most important energy systems.
8. Basic types of steam generators, energy balance, operating characteristics and modes of regulation.
9. Economic and ecological effects of cogeneration production, trends, "small cogeneration".
10. CCGT cycles, trends, possibilities and limits of use in the Central European region. Ecological effect.
11. Long-distance heat supply, operational issues, energy intensity.
12. The secondary circuit is, function analysis, operational and regulatory characteristics, safety and environmental issues.
13. Drain the energy in the energy, heat pumps, balances, operational capabilities and practical limits of applicability
14. Reserve
2. Qualitative evaluation of basic heat technical processes, thermal cycles in the energy sector.
3. Energy intensity in the transportation of liquids and gases, the working point, the energy regulatory assessment methods.
4. The steam turbine, basic principal, basic balance and output characteristics of the basic types of steam turbines.
5. Ways power control condensation and heat circulation. Turbine with controlled steam draw.
6. Condensation, cooling circuits, analysis of operating failures of condensation systems. Impact on the economy of operation of the unit.
7. Synergies and operational linkages and regulatory machinery in the most important energy systems.
8. Basic types of steam generators, energy balance, operating characteristics and modes of regulation.
9. Economic and ecological effects of cogeneration production, trends, "small cogeneration".
10. CCGT cycles, trends, possibilities and limits of use in the Central European region. Ecological effect.
11. Long-distance heat supply, operational issues, energy intensity.
12. The secondary circuit is, function analysis, operational and regulatory characteristics, safety and environmental issues.
13. Drain the energy in the energy, heat pumps, balances, operational capabilities and practical limits of applicability
14. Reserve
Exercises outlines
1. Calculation of basic technical-economic indicators of energy circulation with condensing turbine.
2. Qualitative evaluation of basic energy transformations of thermal energy cycle with steam turbine.
3. Evaluation of the effect of failures in the regenerative heating system on the basic indicators of operating economics of the block.
4. Energy intensity of pumping systems in power engineering, energy assessment of used control methods.
5. Energy intensity of flue gas and air transport, energy savings caused by choice of optimal regulation.
6. Energy balance of a steam turbine with unregulated consumption, turbine behavior when steam flow changes.
7. Calculation of the influence of turbine power control on the operating economics of the block for basic control methods.
8. Assessment of the influence of the most frequent defects in condensation and cooling circuit on technical and economic indicators of the block.
9. Basic quantitative and qualitative energy balance of steam generator, gross calorific value, calorific value, main losses.
10. Approximate calculation of parameters needed for determination of economic and ecological effects of small cogeneration.
11. Energy balance of CCGT, familiarization with modern CCGT circulation
12. Indicative calculation of energy performance in long-distance gas transport. Analysis of operating parameters influence.
13. Introduction to the secondary cycle of nuclear power plant. Basic energy and mass balance of separator and superheater.
14. Reserve
2. Qualitative evaluation of basic energy transformations of thermal energy cycle with steam turbine.
3. Evaluation of the effect of failures in the regenerative heating system on the basic indicators of operating economics of the block.
4. Energy intensity of pumping systems in power engineering, energy assessment of used control methods.
5. Energy intensity of flue gas and air transport, energy savings caused by choice of optimal regulation.
6. Energy balance of a steam turbine with unregulated consumption, turbine behavior when steam flow changes.
7. Calculation of the influence of turbine power control on the operating economics of the block for basic control methods.
8. Assessment of the influence of the most frequent defects in condensation and cooling circuit on technical and economic indicators of the block.
9. Basic quantitative and qualitative energy balance of steam generator, gross calorific value, calorific value, main losses.
10. Approximate calculation of parameters needed for determination of economic and ecological effects of small cogeneration.
11. Energy balance of CCGT, familiarization with modern CCGT circulation
12. Indicative calculation of energy performance in long-distance gas transport. Analysis of operating parameters influence.
13. Introduction to the secondary cycle of nuclear power plant. Basic energy and mass balance of separator and superheater.
14. Reserve
Literature
Moran, M.,J., Shapiro, H.,N.: Fundamentals of Engineering Thermodynamics. Wiley, 2008.
Cengel,Z., Boles, M.,A.: Thermodynamics An Engineering Approach. McGraw-Hill, 2005.
Cengel,Z., Boles, M.,A.: Thermodynamics An Engineering Approach. McGraw-Hill, 2005.
Requirements
No data.