User:Milton Beychok/Sandbox: Difference between revisions
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In power plants burning pulverized coal, wet flue gas desulfurization (FGD) that contacts the flue gases with lime slurries (in what are called wet lime scrubbers) can achieve 95% sulfur dioxide removal without additives and 99+% removal with additives. Wet FGD has the greatest share of the FGD usage in the United States and it is commercially proven, well established technology.<ref name=MIT/> | In power plants burning pulverized coal, wet flue gas desulfurization (FGD) that contacts the flue gases with lime slurries (in what are called wet lime scrubbers) can achieve 95% sulfur dioxide removal without additives and 99+% removal with additives. Wet FGD has the greatest share of the FGD usage in the United States and it is commercially proven, well established technology.<ref name=MIT/> | ||
The typical older FGD units in power plants burning pulverized coal within the United States achieve sulfur dioxide emission levels of about 0.340 kg/MWh (0.22 lb SO<sub>2 </sub>/10<sup>6</sup> Btu), which meets the level to which those units were permitted. | The typical older FGD units in power plants burning pulverized coal within the United States achieve average sulfur dioxide emission levels of about 0.340 kg/MWh (0.22 lb SO<sub>2 </sub>/10<sup>6</sup> Btu), which meets the level to which those units were permitted. | ||
The lowest demonstrated sulfur dioxide emission level (in 2005) for power plants burning pulverized high-sulfur coal within the United States was 1.08 kg/MWh (0.07 lb SO<sub>2 </sub>/10<sup>6</sup> Btu) and 0.046 kg/MWh (0.03 lb SO<sub>2 </sub>/10<sup>6</sup> Btu) for plants burning low-sulfur pulverized coal.<ref name=MIT/> | |||
Revision as of 00:32, 1 December 2008
Flue gas desulfurization
Partial flue gas desulfurization (FGD) can achieve about 50-70 % removal of sulfur dioxide by the injection of dry limestone just downstream of the the air preheater. The resultant solids are recovered in the ESPs along with the fly ash.
In power plants burning pulverized coal, wet flue gas desulfurization (FGD) that contacts the flue gases with lime slurries (in what are called wet lime scrubbers) can achieve 95% sulfur dioxide removal without additives and 99+% removal with additives. Wet FGD has the greatest share of the FGD usage in the United States and it is commercially proven, well established technology.[1]
The typical older FGD units in power plants burning pulverized coal within the United States achieve average sulfur dioxide emission levels of about 0.340 kg/MWh (0.22 lb SO2 /106 Btu), which meets the level to which those units were permitted.
The lowest demonstrated sulfur dioxide emission level (in 2005) for power plants burning pulverized high-sulfur coal within the United States was 1.08 kg/MWh (0.07 lb SO2 /106 Btu) and 0.046 kg/MWh (0.03 lb SO2 /106 Btu) for plants burning low-sulfur pulverized coal.[1]
Coal-fired power plants also emit large quantities of carbon dioxide (CO2) which is not a pollutant in the traditional sense. In fact, it is essential for all plant life on Earth through photosynthesis. However, it is a greenhouse gas considered to have a major role in so-called global warming.
50% of the electricity generated in the U.S. is from coal.2
� Th ere are the equivalent of more than fi ve hundred, 500
megawatt, coal-fi red power plants in the United States with
an average age of 35 years.2
� China is currently constructing the equivalent of two, 500
megawatt, coal-fi red power plants per week and a capacity
comparable to the entire UK power grid each year.3
� One 500 megawatt coal-fi red power plant produces approximately
3 million tons/year of carbon dioxide (CO2).3
� Th e United States produces about 1.5 billion tons per year of
CO2 from coal-burning power plants.
� If all of this CO2 is transported for sequestration, the quantity
is equivalent to three times the weight and, under typical
operating conditions, one-third of the annual volume of
natural gas transported by the U.S. gas pipeline system.
� If 60% of the CO2 produced from U.S. coal-based power
generation were to be captured and compressed to a liquid
for geologic sequestration, its volume would about equal the
total U.S. oil consumption of 20 million barrels per day.