Carbon dioxide capture interface and power generation facility
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F01K-023/10
F01K-023/06
F23C-010/16
출원번호
US-0013483
(2011-01-25)
등록번호
US-8752384
(2014-06-17)
발명자
/ 주소
Polvi, Esko Olavi
출원인 / 주소
Polvi, Esko Olavi
대리인 / 주소
Cohen & Grigsby, PC
인용정보
피인용 횟수 :
0인용 특허 :
3
초록▼
An interface for a pressurized fluidized bed combustion facility is disclosed that enables future addition of carbon dioxide capture technology to capture facility flue gas emissions. The interface includes a gas to water pressurized heat recovery steam generator to cool facility flue gas and provid
An interface for a pressurized fluidized bed combustion facility is disclosed that enables future addition of carbon dioxide capture technology to capture facility flue gas emissions. The interface includes a gas to water pressurized heat recovery steam generator to cool facility flue gas and provide steam to the facility steam turbine generator. A VFD motor and flue gas expander are coupled to a combustion air compressor to energize the facility. The expander is synchronized over a SSS-clutch to drive the compressor. The interface in combination with carbon capture technology and methods for conditioning flue gas are also disclosed.
대표청구항▼
1. An interface for reducing emissions from a pressurized fluidized bed combustion facility, said interface comprising: an air compressor that is connected to the pressurized fluidized bed combustion facility and that supplies compressed air to the fluidized bed combustion facility;a gas to water pr
1. An interface for reducing emissions from a pressurized fluidized bed combustion facility, said interface comprising: an air compressor that is connected to the pressurized fluidized bed combustion facility and that supplies compressed air to the fluidized bed combustion facility;a gas to water pressurized heat recovery steam generator that receives flue gas from the fluidized bed combustion facility at a first input and that receives water at a second input, said heat recovery steam generator also having a first output that discharges flue gas and a second output that discharges steam at times when the temperature of flue gas that is discharged at the first output is lower than the temperature of flue gas that is received at the first input;a steam turbine generator that receives steam from the second output of the gas to water pressurized heat recovery steam generator, said steam turbine generator generating electrical energy in response to steam inflow from the pressurized heat recovery steam generator, said steam turbine generator being electrically connected to a motor that powers said air compressor; anda flue gas expander that is in communication with the first output of said gas to water pressurized heat recovery steam generator, said flue gas expander being mechanically connected to said air compressor to power said air compressor in response to flue gas from the pressurized heat recovery steam generator, said flue gas expander powering said air compressor in combination with the motor that is electrically connected to the steam turbine generator. 2. The interface of claim 1 further comprising a carbon dioxide removal unit that has an input that is in communication with the first output of the gas to water pressurized heat recovery steam generator, said carbon dioxide removal unit having an output that is in communication with the flue gas expander, said carbon dioxide removal unit removing carbon dioxide from the flue gas that is provided to the flue gas expander. 3. The interface of claim 1 further comprising at least one heat exchanger that has an input that is in communication with the first output of the gas to water pressurized heat recovery steam generator, said heat exchanger having an output that is in communication with said flue gas expander, wherein the temperature of flue gas that is discharged at said output is lower than the temperature of flue gas received at said input. 4. The interface of claim 3 further comprising a pollutant reduction unit that is in communication with the second output of the gas to water pressurized heat recovery steam generator, said pollutant reduction unit also being in communication with said flue gas expander, said pollutant reduction unit removing air pollutants from flue gas that is discharged from the first output of said gas to water pressurized heat recovery steam generator. 5. The interface of claim 4 further comprising a carbon dioxide removal unit that has an input that is in communication with the first output of the gas to water pressurized heat recovery steam generator, said carbon dioxide removal unit having an output that is in communication with the flue gas expander, said carbon dioxide removal unit removing carbon dioxide from the flue gas that is provided to the flue gas expander. 6. The interface of claim 1 further comprising a duct firing element that is included in the gas to water pressurized heat recovery steam generator. 7. An interface that enables the selective addition of carbon dioxide capture from the flue gas of a pressurized fluidized bed combustion facility, said interface comprising: a combustion air compressor, configured to supply combustion air to the combustion facility;a VFD electric motor coupled to the combustion air compressor;a gas to water pressurized heat recovery steam generator that is connected to a water supply and to a steam turbine generator of the combustion facility, said pressurized heat recovery steam generator also being connected to the pressurized bed combustion facility and receiving pressurized flue gas from the fluidized bed combustion facility, said heat recovery steam generator lowering the temperature of the pressurized flue gas from the combustion facility and providing steam to the steam turbine generator of the combustion facility;a steam turbine generator that receives steam from the heat recovery steam generator and that generates electrical power in response to said steam from the heat recovery steam generator and provides electrical power to said VFD electric motor;a feedwater heat exchanger for preheating feedwater of the combustion facility and cooling the pressurized flue gas;a pollutant reduction unit configured to remove pollutants from the cooled pressurized flue gas from the feedwater heat exchanger; anda flue gas expander driven by the flue gas from the pollutant reduction unit, wherein the expander is synchronized over an SSS-clutch to drive the compressor in combination with the VFD electric motor. 8. The interface of claim 7, further comprising a pressurized carbon dioxide capturing process unit for treating the flue gas of the feedwater heat exchanger or pollutant reduction unit prior to using the flue gas to drive the flue gas expander. 9. The interface of claim 7, further comprising a second feedwater heat exchanger configured to cool the flue gas from the pollutant reduction unit. 10. The interface of claim 7, further comprising a duct firing unit configured to increase the thermal output of the heat recovery steam generator. 11. The interface of claim 7, further comprising selective catalytic reduction or an ammonia injection, or both, configured to remove nitrogen oxides from the flue gas of the combustion facility. 12. The interface of claim 7, wherein the pollutant reduction unit comprises a sulfur dioxide absorber configured to remove sulfur from the flue gas cooled down in the feedwater heat exchanger, and a particulate matter reduction unit configured to remove particulate matter from the flue gas. 13. The interface of claim 12, wherein the sulfur dioxide absorber is selected from the group consisting of bicarbonate injection, wet scrubber, spray drying adsorption, and flue gas desulfurization. 14. The interface of claim 12, wherein the sulfur dioxide absorber is designed to reduce or remove the sulfur dioxide from the flue gas in an amount to control the consumption of capturing agent used in the carbon dioxide capturing process unit. 15. A method to condition pressurized flue gas from a pressurized fluidized bed combustion facility to supplement the power needed to run the combustion facility comprising: reducing the temperature of flue gas from the combustion facility in a gas to water pressurized heat recovery steam generator;providing steam from the heat recovery steam generator to a steam turbine generator of the combustion facility;reducing the temperature of pressurized flue gas from the heat recovery steam generator in a feedwater heat exchanger;reducing pollutants from the flue gas; andexpanding the flue gas in a gas expander to drive a compressor, wherein the compressor generates compressed air to fuel the combustion facility. 16. The method of claim 15, further comprising the step of synchronizing the gas expander over a SSS-clutch to drive the compressor. 17. The method of claim 15, further comprising the step of powering the compressor with a VFD motor. 18. The method of claim 15, further comprising the step of capturing carbon dioxide from the flue gas in a pressurized carbon dioxide capturing process unit, before expanding the flue gas. 19. The method of claim 18, further comprising the step of directing the carbon dioxide depleted flue gas to a flue gas stack. 20. The method of claim 15, wherein the reducing pollutants comprises: removing or reducing sulfur dioxide from the flue gas from the feedwater heat exchanger in a sulfur dioxide absorber; andremoving particulate matter from the flue gas using a particulate matter reduction unit.
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이 특허에 인용된 특허 (3)
Heyn Klaus (Essen DEX) Pogrzeba Hans J. (Essen DEX), Installation for recovering energy from solid fossil fuels, more particularly bituminous coal high in inerts.
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