SYSTEM STUDIES ON ADVANCED POWER GENERATION TECHNOLOGIES FOR 21st CENTURY

1. SYSTEM STUDIES ON ADVANCED POWER GENERATION TECHNOLOGIES FOR 21st CENTURY Dr V K Sethi Director MOP/ CEA Super Critical Boilers

2. o Super Critical PC Power Plant (15 C Amb.) 60 Super Critical PC Power Plant (Indian Condition) o IGCC (15 C Amb) 55 IGCC (Indian Condition) Sub Critical PC Power Plant (Indian Condition) 50 o 1500 C o 1300 C o 623 C o Net Thermal Efficiency (%) 600 C 45 o 566 C 40 Ceramic gas turbine o 1184 C o 650 C 35 o 540 C 30 1995 2000 2005 2010 1990 Year of commercial use Fig.1 EFFICIENCY IMPROVEMENT FORECAST CONVENTIONAL Vs IGCC Super Critical Boilers

3. PULVERIZED COAL (PC) PC+FGD 950* 100 IGCC 800* 3 * mg/m 80 60 50* 50* PERCENTAGE OF PC PLANTS 40 200* 200* 20 100* 5* 50* 0 Particulates NO SO x 2 Fig.2 COMPARISON OF EMISSIONS FROM VARIOUS COAL FIRED POWER PLANT Super Critical Boilers

4. Measures to improve Plant Efficiency And / or Heat Rate Turbine side measures : • Higher steam parameters (Pr. & Temp.) • Adoption of double reheat cycle • Enhancing Regenerative feed heating • Reduced Auxiliary power consumption • Increase in condenser vacuum Boiler design to accommodate the first four requirements Super Critical Boilers

5. Steam generation process Super Critical Boilers

6. Sub-Critical vs Super Critical Description Sub Critical Super Critical Full Load Pressure <190 atm >240 atm Flow in Water wall 2-Phase 1-Phase Cycle efficiency Base + 2 - 3 % Approx Fuel saving Base +8 - 10 % Approx Boiler weight Base + 10 % Stages of reheat 1 2 Preferred Preference on date Maintaining Cyclic (Yet to start in India) Super Critical Boilers

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11. Increase in Efficiency due to steam parameters Super Critical Boilers

12. Effect of steam parameters on coal consumption(500 MWe, 6500 h/a, LHV 13917 kJ/kg)Coal consumption in kg/MWh Super Critical Boilers

13. Evolution of Higher steam parameters • 1980s: Pressure increased from 175-180 bar to 225 bar ;temp mostly around 540 deg C • 1990s: Pressures raised to 285 bar; temp raised to 565-580-600 Deg C • Today 255 bar 568/568 Deg C commonly used 300 bar & 620 Deg C under development Super Critical Boilers

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16. STEAM TO TURBINE STEAM TO TURBINE SH SH ECO DRUM HEAT HEAT DOWN COMER Water Wall Water Wall ECO ORIFICE CIRC. PUMP DRUM vs ONCE THROUGH Pressure Sub critical Sub & super Critical Steam Separation Drum Separator (Low loads) Types Natural / Assisted (Sulzer) / (Benson) Burner Panel Straight tube Spiral Tube / Straight (MHI) Load Change Base Faster Cold Start 4-5 Hours 2 Hours Hot Start 1-2 Hours 0.5 Hours Super Critical Boilers

17. Drum type boiler • Steam generation essentially takes place in furnace water walls • Fixed evaporation end point - the drum • Steam -water separation takes place in the drum • Separated water mixed with incoming feed water and fed back to ww lower drum by means of boiler water circulating pumps (BWCPs). Super Critical Boilers

18. Drum type boiler • Natural Circulation Boiler Circulation through water walls by thermo-siphon effect • Controlled Circulation Boiler At higher operating pressures (just below critical pressure levels), thermo-siphon effect supplemented by pumps to ensure safety of furnace wall tubes. Super Critical Boilers

19. THE CONCEPT The mass flow rate thru’ all heat transfer circuits from Eco. inlet to SH outlet is kept same except at low loads wherein recirculation is resorted to protect the water wall system Super Critical Boilers

20. Once Through Boiler-Concept Once through system Super Critical Boilers

21. Once Through Boiler • Once -through forced flow through all sections of boiler (economiser, water walls & superheater) • Feed pump provides the driving head • Suitable for sub critical & super critical pressures Super Critical Boilers

22. Once -thru Boiler Advantages: • Quick response to load changes • Shorter start up time • Better suited for sliding pressure operation • Steam temperature can be maintained over wider load range under sliding pressure • Higher tolerance to varying coal quality • Suitable for sub critical & super critical pressures Super Critical Boilers

23. Once -through Boiler Requirements : • Stringent water quality • Sophisticated control system • Low load circulation system • Special design to support the spiral furnace wall weight • High pressure drop in pressure parts • Higher design pressure for components from feed pump to separator. Super Critical Boilers

24. Once -through Boiler Characteristics : • Provides Quicker response to TG load changes • Supports achievement of better heat rate at lower loads • Higher furnace wall pressure drop and consequent higher feed pump auxiliary power consumption • Needs ultra pure quality feed water - Cannot operate under conditions of condenser leak Super Critical Boilers

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26. Furnace Arrangement SPIRAL TYPE VERTICAL TYPE Super Critical Boilers

27. Once -through Boiler Operating Range Super Critical Boilers

28. Sliding Pressure Operation Super Critical Boilers

29. Advantages of sliding pressure • Higher efficiency • Less auxiliary power • Less fatigue of pressure parts Super Critical Boilers