control of nox in thermal power plants
TRANSCRIPT
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CONTROL OF NOx IN THERMAL POWER
PLANTS
submitted byPATI JAYA CHANDRA113MN0480
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WHY?
NO 2 is an air pollutant.
NO 2 reacts in the atmosphere to form ozone (O3) and acid rain.
Tropospheric ozone has been and continues to be a significant air
pollution problem in the United States and is the primary constituent
of smog.
Standard for NO2 is 0.053 parts per million (ppm) in the atmosphere.
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WHERE DOES NOx COME FROM?
Auto mobiles & other mobile sources
Thermal Power Plants Other sources
50% 20% 30%
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CONTROL OF NOx:• NOx control can be achieved by:
· Catalytic Combustion
· Modification of operating conditions
· Tail-end control equipment
Selective Catalytic Reduction
Selective Non - Catalytic Reduction
Electron Beam Radiation
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Catalytic Combustion
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Catalytic Combustion
• A catalyst is used to react fuel with air at a lower temperature than normal
combustion at which generation of significant amounts of NOx does not
occur.
• Emissions under 1 ppm NOx have been reported.
• This technology has a relatively high capital and operation and maintenance
cost because there is both a substantial initial investment and a replacement
cost for the catalyst
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Modification Of Operating Conditions
Off-stoichiometric combustion (staged combustion)
· Initially, less air is supplied to bring about incomplete combustion.
· Nitrogen is not oxidized. Carbon particles and CO are released.
· In the second stage, more air is supplied to complete the combustion of
carbon and carbon monoxide.
· 30% to 50% reductions in NOx emissions are achieved.
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Staged Combustion
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Modification Of Operating ConditionsSteam/water injection:
• To reduce combustion temperature, steam or water can be mixed with the air
flow.
• This lowers combustion temperature to below 1,400F to limit NOx generation to
about 40 ppm.
• This can cause the concentration of CO and unburned hydrocarbons emitted from
a turbine to be increased.(drawback)
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Selective Catalytic Reduction• In this process, the nitrogen oxides in the flue gases are reduced to nitrogen
• During this process, only the NOx species are reduced
• NH3 is used as a reducing gas
• The catalyst is a combination of titanium and vanadium oxides. The reactions are
given below :
• 4 NO + 4 NH3 + O2 -----> 4N2 + 6H2O
• 2NO2 + 4 NH3+ O2 -----> 3N2 + 6H2O
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Selective Catalytic Reduction
• Selective catalytic reduction catalyst is best at around 300 to 400C
• Typical efficiencies are around 80 %.
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Selective Non-catalytic Reduction (SNR)• At higher temperatures (900-1000C), NH3 will reduce NOX to nitrogen without a
catalyst.
• At NH3 : NOX molar ratios 1:1 to 2:1, about 40-60%reduction is obtained.
• SNR is cheaper than SCR in terms of operation cost and capital cost.
• Tight temperature controls are needed.
• At lower temperatures, un-reacted ammonia is emitted.
• At higher temperatures ammonia is oxidized to NO.
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Electron Beam Radiation• This treatment process is under development, and is not widely used.
• Irradiation of flue gases containing NOx or SOx produce nitrate and sulfate ions.
• The addition of water and ammonia produces NH4NO3, and (NH4)2SO4
• The solids are removed from the gas, and are sold as fertilizers.
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References:1. RAO M.N. & RAO H, Air pollution, Tata McGraw Hill.
2. Mahajan S.P., pollution control in process industries, Tata McGraw Hill.
3. https://www3.epa.gov/ttncatc1/dir1/fnoxdoc.pdf