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Steam turbine for steam-gas block
Kober, Ondřej ; Fiedler, Jan (referee) ; Kracík, Petr (advisor)
This master’s thesis deals with the design of two variants of a condensing steam turbine for a steam-gas unit. In the first variant, steam bleeding from the turbine for low-pressure regeneration is considered, in the second variant heat regeneration would be provided by a heat recovery steam generator, which is not the subject of the master’s thesis. Three unregulated steam extractions for the deaerator and two low-pressure heaters are considered for the turbine with steam bleeding. Both turbines were designed with an impulse governing stage and a reaction blading. The result of the design of bleeding variant is a turbine with a speed of 7000 min-1 with 7 cones, 33 stages with power output of 13,69 MW and an efficiency of 81,83%. The turbine without bleeding has a speed of 6500 min-1, 7 cones, 38 degrees, power output of 14,13 MW and an efficiency of 81,97%. The consumption characteristics are given for both turbines at the end. For the steam bleeding turbine, a drawing of the turbine section is attached to the thesis.
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Steam Turbine for Biomass Power Plant
Ingr, Adam ; Fiedler, Jan (referee) ; Kracík, Petr (advisor)
This master‘s thesis deals with thermodynamic calculation of condensing steam turbine with controlled extraction point for heat exchanger, into biomass power plant block. Rated output of steam turbine is 6.5 MW and rated output of heat exchanger is 4.5 MW. At the beginning of the thesis is explained the heat scheme and the effect of heat regeneration on the design of turbine. Attention was also paid to the heat equation of individual thermal diagram devices and the calculation of the steam mass flow rate. The next part is focused on thermodynamic calculation of the turbine, followed by mechanical stress calculations. The calculation is divided into preliminary design and detailed calculation. At the end, the performance analysis of the designed turbine is made.
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Condensing steam turbine
Vymětalík, Zbyněk ; Fiedler, Jan (referee) ; Kracík, Petr (advisor)
The topic of this diploma thesis is a condensing steam turbine with one regulated steam extraction. The first part contents design and balance of heat scheme. The heat scheme is the basis for the main part of this work, which is the thermodynamic design of the turbine with reaction blades. At the end, the characteristics of the turbine are created. Drawing of the turbine section is attached to this thesis.
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Extraction Condensing Steam Turbine
Drápela, Jakub ; Kracík, Petr (referee) ; Fiedler, Jan (advisor)
This diploma thesis describes a design of condensing steam turbine out of entered data of vapor parameters. There is selected a reaction blading type according to a conception of the company PBS Energo PLC. The turbine has one controlled extraction and three uncontrolled ones. The work also includes a proposal of thermal scheme, bearing and gearbox assignment. Furthermore there is also made a draft design of longitudinal section turbine
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Steam Turbine for Biomass Power Plant
Doseděl, Jakub ; Fiedler, Jan (referee) ; Kracík, Petr (advisor)
The aim of this diploma thesis is a design of a condensing steam turbine based on technical specification of inlet steam - maximal mass flow 120 t/h, temperature 440 °C; on temperature in deaerator 125 °C; on mass flow 0 – 60 t/h and pressure 3,0 bar(a) of regulated steam extraction and on ambient temperature in the vicinity 25 °C. The result contains steam turbine with reaction blading, work output 28,76 MWe and efficiency 82 %.
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Condensing Steam Turbine C55
Borýsek, Václav ; Fiedler, Jan (referee) ; Kracík, Petr (advisor)
This diploma thesis deals with the design of a steam condensing turbine for intake steam of pressure 125 bar, temperature 540 °C and maximal intake of steam into the turbine 130 t/h. A thermal scheme is designed, including low-pressure and high-pressure regeneration, an air condenser, a feed tank and a boiler. Afterwards a thermodynamic design of a condensing turbine is made with an A-wheel type regulating stage and a stage part with reaction blades. The design of the blades is strength-tested. Then is made the design of the compensating piston and the sealing system. In the end the characteristics of the turbine for non-design steam flows is plotted. The designed turbine has a power of 34644 kW, has a thermodynamic efficiency of 85.1% and a reheat factor of 1.046.
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Steam turbine for an industrial CHP plant
Tretera, Michal ; Fiedler, Jan (referee) ; Kracík, Petr (advisor)
This diploma thesis deals with the thermodynamic design of a backpressure steam turbine. The mass flow of steam through the turbine is determined based on the required heat output, which is transferred in a heat exchanger at the turbine outlet. The governing stage of the turbine is in form of an impulse stage, with optimization of degree of reaction included. During the optimization, a suitable rotor blade was chosen as well as its size. The governing stage is followed by fifteen stages of reaction blading with the stage loading coefficient in the range of 2,75 to 2,80. The governing stage and the reaction blading both meet the mechanical strength requirements. Balancing piston, sealing system and bearings are also designed. Finally, a turbine characteristic is created as well as a longitudinal section. The designed turbine has a speed of 10 000 rpm. While supplying the required heat output, it has a terminal power output of 5 863,4 kW and a thermodynamic efficiency of 84,69 %.
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Retrofit steam turbine 210 MW
Sedláček, Tomáš ; Fiedler, Jan (referee) ; Kracík, Petr (advisor)
This master‘s thesis deals with the retrofit of a three-body condensing steam turbine with an output of 210 MW. The first part deals with the thermal diagram, which is designed with seven unregulated steam extractions and one extraction for degassing. The mass flow is determined here on the basis of the required power and three thermal diagrams are made for different outputs. In the next part, the regulation stage in the A-wheel design was designed, including the strength control. The main subject is the design of the stage part, which is divided into preliminary and a detailed calculation relating only to the high pressure section of the steam turbine. During the optimization phase, a detailed calculation is linked to the thermal diagram and the regulation stage. The resulting blading of the HP section is optimized based on the selected properties, including strength control. An orientation design of the compensating piston together with the sealing system is also included, for selected diameters, due to the unknown action of the axial force from the MP and LP section. Furthermore, a strength check of the inner nodes of the existing body of the high-pressure section is performed, where the need to use the inner body arises. The designed HP section, including the regulation stage, achieves an internal power of 69,5 MW, an internal thermodynamic efficiency of 92 % and a reheat factor of 1,0168.
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Condensing steam turbine
Prinz, František ; Škorpík, Jiří (referee) ; Kracík, Petr (advisor)
The main topic of this master thesis is the design of condensing steam turbine. In the beginning the heat scheme with low pressure regeneration is calculated. There are chosen 2 low pressure heat exchangers and 3 steam outlets from the turbine. In the main part the thermodynamic proposal with reaction blades is designed, which consists of the regulating stage and the stage part of turbine. The survivability of the turbine is checked by the calculation of mechanical strength. In the end the turbine is checked at reduced mass flow and the turbine characteristic is plotted. The designed steam turbined has a regulating stage and 34 stages in the stage part, has a power of 45873 kW with thermodynamic efficiency of 83.6%. The reheat factor is 1.052.
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Steam turbine for biomass power plant
Chumchal, Ondřej ; Fiedler, Jan (referee) ; Kracík, Petr (advisor)
This thesis deals with the design of a steam turbine for a biomass unit in two alternative solutions, with and without gearbox, for a given 30 MW clamp power. The design of both solutions works with the same heat cycle scheme, but the parameters at the low-pressure heater or at the inlet to the feed tank differ depending on the steam conditions in the turbine intakes. In the first part of the paper, a thermal balance scheme with low pressure regeneration is proposed and the steam flow through the turbine is calculated. Both variants have three unregulated bleeds, one of which is led to the degasification feed tank. For both variants a regulative stage is designed using impulse system of blading and a stage section using reactive blading. The work also includes the determination of axial force and the associated design of the balancing piston and gland steam system. Appropriate bearings were selected for the given force stresses. A graphical comparison of the two variants is presented in the paper, together with the operating characteristics. Finally, a conceptual section drawing of the steam turbine was made. The result is a turbine without gearbox with 36 stages and an efficiency of 82%, then with gearbox at 5400 min-1 with 27 stages and a thermodynamic efficiency of 86.7%.
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