>The 600 MW coal-fired Kelvin power station, in Isando, Ekurhuleni, has installed a 300 m3/h flue gas emissions capturing pilot project, which removes carbon dioxide (CO₂), nitrogen oxides and sulphur oxides to make sulphuric acid, ammonium sulphate and ammonium bicarbonate (ABC) crystals.
>These are industrial products, which can be used as industry inputs and to make fertiliser. Specialist industrial and agricultural chemicals company Omnia has developed a marketable fertiliser formulation using converted inorganic salts from the plant, which it demonstrated at the site on March 20.
>The CoalCO₂-X programme is aimed at harnessing the components of the flue gas for the circular production of products such as diesel and fertilisers, as well as to convert CO₂ from South African coal-fired power plants using ammonia and hydrogen, and eventually using green ammonia and green hydrogen.
>The entire plant is post-precipitation, meaning it comes after the power plant’s industrial processes are complete. The process is continuous and can be scaled up to hundreds of thousands of cubic meters an hour, EPCM Global Engineering CEO Tumi Kgomo explained during a site visit to the plant.
>The flue gases are first extracted into a quenching system to lower the temperature and water is added to maximise the humidity, while heavy metals and any remaining particulate matter are also removed at this stage.
>The flue gases are then sent on to the sulphur oxides reactor, where the sulphur oxides are removed and sulphuric acid produced using water. The gases then enter a cooling stack.
>Flue gases are sent on to the CO₂ reactor, which uses ammonia to remove the CO₂ and produce ABC crystals. These can be used as a fertiliser base.
>From here, the remaining flue gases continue to the ammonia reactor where sulphuric acid is used and ammonium sulphate produced.
>The final part of the process is the nitrogen oxides reactor that removes these gases, and the cleaned gases are then released.
>The output readings Engineering News saw on March 20 during the demonstration was that sulphur oxides were reduced from 259 parts per million (ppm) in the flue gases to 0 ppm, and nitrogen oxides were reduced from 459.5 ppm to 0.2 ppm.
>CO₂ was reduced from 7.76% of the gases to 5.62%. The concentration of CO₂ in the Kelvin power station’s flue gases varies between about 7% and 10% of volume.
>However, hard-to-abate industrial processes that liberate more CO₂ than they do for primary energy consumption, such as cement making, have higher percentages of about 15% to 25% CO₂ in their flue gases and a greater proportion of the gas can be captured, Kgomo said.
>The pilot plant is aimed at achieving a 50% reduction in CO₂, but the partners say the final process should be capable of removing 90% of the gas.
>The main aim of the multi-pollutant abatement pilot plant was to help power stations to meet emissions targets, as well as to give them sufficient capacity to meet higher emissions standards in the future, said Kgomo.
>”The plant fundamentally shifts the opportunities for functional compliance that is not a sunk cost. The break-even point for the plant is about five to seven years,” he noted.
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>The 600 MW coal-fired Kelvin power station, in Isando, Ekurhuleni, has installed a 300 m3/h flue gas emissions capturing pilot project, which removes carbon dioxide (CO₂), nitrogen oxides and sulphur oxides to make sulphuric acid, ammonium sulphate and ammonium bicarbonate (ABC) crystals.
>These are industrial products, which can be used as industry inputs and to make fertiliser. Specialist industrial and agricultural chemicals company Omnia has developed a marketable fertiliser formulation using converted inorganic salts from the plant, which it demonstrated at the site on March 20.
>The CoalCO₂-X programme is aimed at harnessing the components of the flue gas for the circular production of products such as diesel and fertilisers, as well as to convert CO₂ from South African coal-fired power plants using ammonia and hydrogen, and eventually using green ammonia and green hydrogen.
>The entire plant is post-precipitation, meaning it comes after the power plant’s industrial processes are complete. The process is continuous and can be scaled up to hundreds of thousands of cubic meters an hour, EPCM Global Engineering CEO Tumi Kgomo explained during a site visit to the plant.
>The flue gases are first extracted into a quenching system to lower the temperature and water is added to maximise the humidity, while heavy metals and any remaining particulate matter are also removed at this stage.
>The flue gases are then sent on to the sulphur oxides reactor, where the sulphur oxides are removed and sulphuric acid produced using water. The gases then enter a cooling stack.
>Flue gases are sent on to the CO₂ reactor, which uses ammonia to remove the CO₂ and produce ABC crystals. These can be used as a fertiliser base.
>From here, the remaining flue gases continue to the ammonia reactor where sulphuric acid is used and ammonium sulphate produced.
>The final part of the process is the nitrogen oxides reactor that removes these gases, and the cleaned gases are then released.
>The output readings Engineering News saw on March 20 during the demonstration was that sulphur oxides were reduced from 259 parts per million (ppm) in the flue gases to 0 ppm, and nitrogen oxides were reduced from 459.5 ppm to 0.2 ppm.
>CO₂ was reduced from 7.76% of the gases to 5.62%. The concentration of CO₂ in the Kelvin power station’s flue gases varies between about 7% and 10% of volume.
>However, hard-to-abate industrial processes that liberate more CO₂ than they do for primary energy consumption, such as cement making, have higher percentages of about 15% to 25% CO₂ in their flue gases and a greater proportion of the gas can be captured, Kgomo said.
>The pilot plant is aimed at achieving a 50% reduction in CO₂, but the partners say the final process should be capable of removing 90% of the gas.
>The main aim of the multi-pollutant abatement pilot plant was to help power stations to meet emissions targets, as well as to give them sufficient capacity to meet higher emissions standards in the future, said Kgomo.
>”The plant fundamentally shifts the opportunities for functional compliance that is not a sunk cost. The break-even point for the plant is about five to seven years,” he noted.