![ Carbon reaction
2C + O2 =2CO [Eco =60kJ/mol]
C + O2 =CO2 [Eco2 =140kJ/mol]
reaction at 1200oC
4C + 3O2 =2CO + 2CO2 (Ratio 1:1)
Reaction at 1700oC
3C + 2O2 = 2CO +CO2 (Ratio 2:1)
It is desirable to supply combustion air at lower temperature
regime in furnace
17](https://image.slidesharecdn.com/generationofelectricityfromcoalparul-150126074852-conversion-gate02/75/generation-of-electricity-from-coal-parul-17-2048.jpg?cb=1668905292)
Generation of electricity from coal parul
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Generation of electricity from coal parul
- 1. 1 DEPARTMENTOF ELECTRICALENGINEERING Seminar Presentation On Generation of Electricity from Coal Parul Institute Of Engineering And Technology Affiliated to Gujarat Technological University, Ahmadabad. Presented By: Swapnil Sharma ME 1st Sem(PS)
- 2. Basic of Power Generation Basic information on Coal/Fuel Oil Combustion Process Power Plant Cycle 4 Main Path come across in any thermal power plant Boilers and Turbines Transmission of Power and Switching 2
- 3. A thermal power station is a power plant in which the Water is heated, turns into steam and spins a steam turbine and does some other work and produce electricity . After it passes through the turbine, the steam is condensed in a condenser and recycled to where it was heated, this is known as a Rankine cycle 3
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- 6. 6 Power Generation, Transmission and Distribution
- 7. 7 Coal Chemical Energy Super Heated Steam Pollutants Thermal Energy Turbine Torque Heat Loss In Condenser Kinetic Energy Electrical Energy Alternating current in Stator Mech. Energy LossASH Heat Loss Elet. Energy Loss
- 8. 8 Overview of Thermal Power Plant
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- 10. Coal - 12000 Ton/day Water – 98000 Cubic meter / day Oil - 100 Cubic meter / day Air - 50000 Tons/ day This also result in the following Ash - 4200 tons/ day CO2 - 30000 tons/ day So2 - 600 tons/ day No2 - 80 tons/ day 10
- 11. 11 NR WR SR ER NER Ennore Kudankulam Kayamkulam Partabpur Talcher/Ib Valley Vindhyachal Korba MAJOR ENERGY RESOURCES IN INDIA LEGEND Coal Hydro Lignite Coastal Nuclear Vizag Simhadri Kaiga Tarapur Mangalore Krishnapatnam RAPP 53,000MW 23,000MW 1,700MW SIKKIM MYANMMAR CHICKEN NECK Cuddalore SRI LANKA COLOMBO NEPAL BHUTAN DESH BANGLA South Madras Pipavav Generation Load-Centre Kolkata Bhubaneswar Patna Lucknow Delhi Mumbai Chennai Bangalore Bhopal Guwahati Jammu Ludhiana Jaipur Gandhinagar Indore Raipur Thiruvananthapuram Kozhikode Hyderabad * Hydro Potential : 1,10,000 > 25,000MW already installed > 19,000MW under implementation > 66,000MW still to be exploited * 90% coal reserves in ER & WR
- 12. 12 Share of Coal in Power Generation Advantages of Coal Fuel •Abundantly available in India •Low cost •Technology for Power Generation well developed. •Easy to handle, transport, store and use Shortcomings of Coal •Low Calorific Value •Large quantity to be Handled •Produces pollutants, ash •Disposal of ash is Problematic •Reserves depleting fast •India’s Coal Reserves are estimated to be 206 billion tonnes. Present consumption is about 450 million tonnes. •Cost of coal for producing 1 unit of electricity (Cost of coal Rs 1000/MT) is Rs 0.75. •Cost of Gas for producing 1 unit of electricity (Cost of Gas Rs 6/SMC) is Rs 1.20. Coal 55% Gas 10% Diesel 1% ydel 6% RES 5% Nuclear 3%
- 13. 13 Coal Transportation •Rail •Truck •Conveyor •Ship Coal production •Surface Mining •Underground Mining Coal Properties •Calorific Value •Grade of Coal (UHV) •Proximate Analysis •Ultimate Analysis •Ash and Minerals •Grindability •Rank •Physical Characteristics Coal Beneficiation (Coal cleaning and reduction in total volume of coal.)
- 14. 14 Coal Analysis Typical composition Proximate Analysis Moisture, Volatile , Ash and Fixed Carbon Ultimate Analysis Hydrogen, Sulphur , Oxygen, Ash and Mineral Content of Ash and Mineral Grind ability Grind a specific coal to the particles size necessary for effective combustion Rank Stage of coal has reached on the coalification Physical Characteristic - Hardness , Color, Weight, Volume
- 15. Carbon, hydrogen, sulfur are sources of heat on combustion Surface moisture removed on heating during pulverization. Inherent moisture and volatiles are released at higher temperature, making coal porous and leading to char/ coke formation. (Thermal preparation stage) 15
- 16. Main reactions 2C + O2 = 2CO + 3950 BTU/lb (Deficit air) C + O2 = CO2 +14093 BTU/lb Secondary reactions 2CO + O2 = 2CO2 + 4347BTU/lb C + CO2 = 2CO -7.25MJ/kg 16
- 17. Carbon reaction 2C + O2 =2CO [Eco =60kJ/mol] C + O2 =CO2 [Eco2 =140kJ/mol] reaction at 1200oC 4C + 3O2 =2CO + 2CO2 (Ratio 1:1) Reaction at 1700oC 3C + 2O2 = 2CO +CO2 (Ratio 2:1) It is desirable to supply combustion air at lower temperature regime in furnace 17
- 18. Hydrogen reaction 2H2 + O2 = 2H2O +61095 BTU/lb Sulfur reaction S + O2 = SO2 + 3980 BTU/lb (undesirable) 18
- 19. Anthracite Semi-anthracite Bituminous Semi-Bituminous Lignite Peat High CV, low VM High CV, low VM Medium CV, medium VM Medium CV, medium VM Low CV, high VM, high TM Very low CV, high VM & TM 19
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- 21. liquid fuels used in power plants Light Diesel Oil (LDO) - Heavy Fuel Oil (HFO) - Droplet formation on atomization (by steam/ compressed air/ mechanical pressurization) Combustion initiation by High energy spark ignition 21
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- 24. 24 one would come across in any thermal power plant layout are - Coal and Ash Circuit - Air and Gas Circuit - Feed Water and Steam Circuit - Cooling Water Circuit
- 25. Wagon Tripler Conveyer Belt Magnetic Separation Crusher (20-25 mm) Bunker Mill Burner 25
- 26. 26 Ash Circuit Bottom Ash Fly Ash (80%) (20%) Slurry Silo Ash Ponds
- 27. Fuel gas Circuit Furnace Super heater Economiser APH ESP ID Fan Chimney Air Circuit FD Fan APH Wind Box Furnace 27
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- 31. Steam generating device for a specific purpose. Capable to meet variation in load demand Capable of generating steam in a range of operating pressure and temperature For utility purpose, it should generate steam uninterruptedly at operating pressure and temperature for running steam turbines. 31
- 32. Raw materials for design of boilers 1. Coal from mines 2. Ambient air 3. Water from natural resources 4. (river, ponds) o Generating heat energy o Air for combustion o Working fluid for steam o generation, possessing heat energy 32 A 500MW steam generator consumes about 8000 tonnes of coal every day It will be considered good, if it requires about 200 cubic meter of DM water in a day It will produce about 9500 tonnes of Carbon di Oxide every day
- 33. 33 ARRANGEMENT OF MAIN BOILER (STEAM GENERATOR) A STEAM GENERATOR IS A COMPLEX INTEGRATION OF THE FOLLOWING ACCESSORIES: * ECONOMISER * REHEATER * BOILER DRUM * DIV PANEL •DOWN COMERS * CCW PUMPS * BOTTOM RING HEADER * BURNERS * WATER WALLS * APHs
- 34. Water Tube Boiler: Here the heat source is outside the tubes and the water to be heated is inside. Most high- pressure and large boilers are of this type. In the water-tube boiler, gases flow over water-filled tubes. These water-filled tubes are in turn connected to large containers called drums. 34
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- 44. 44 The steam turbine is a form of heat engine that derives much of its improvement in thermodynamic efficiency from the use of multiple stages in the expansion of the steam
- 45. 45 Turbine
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- 48. 48 Switchyard One line Diagram G Transfer Bus 400 KV Main Bus II Main Bus I CB CB CB GT 20.5/400KV Gen Bay Feeder Bay Bus Isolator Transfer Bus Bay
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