Efficient combined cycle power plant with COcapture and a combustor arrangement with separate flows
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02C-001/00
F02C-003/30
F02C-003/20
F02C-007/08
F02C-007/12
출원번호
US-0545156
(2004-02-09)
등록번호
US-7490472
(2009-02-17)
우선권정보
NO-20030682(2003-02-11); NO-20031550(2003-04-04)
국제출원번호
PCT/NO04/000036
(2004-02-09)
§371/§102 date
20050927
(20050927)
국제공개번호
WO04/072443
(2004-08-26)
발명자
/ 주소
Lynghjem,Arne
Jakobsen,Jon
Kobro,Henrik
Lund,Arnfinn
출원인 / 주소
Statoil ASA
대리인 / 주소
Foley & Lardner LLP
인용정보
피인용 횟수 :
69인용 특허 :
4
초록▼
The invention relates to a method for inter alia to increase the energy and cost efficiency of a gas power plant or a thermal heat plant with CO2 capturing. The power plant comprises gas turbine plants (12,12') comprising compressor units (13,13') and turbine units (14,14') and further comprises a c
The invention relates to a method for inter alia to increase the energy and cost efficiency of a gas power plant or a thermal heat plant with CO2 capturing. The power plant comprises gas turbine plants (12,12') comprising compressor units (13,13') and turbine units (14,14') and further comprises a combustor (10). The combustor (10) is working in principle with to separate gas part streams where one gas part stream flows internally through the flame tube (40) of the combustor (10), while the other gas part stream is flowing along the exterior of the flame tube (40). The first gas part stream comprises additional air and re-circulated, un-cleaned flue gas from the combustor (10), said gases being combusted together with fuel inside the flame tube (40). The second gas part stream comprises cleaned flue gas which is heated up at the exterior of the flame tube (40) while the flame tube (40) is cooled down. The invention comprises also a power plant, a combustor and a CO2 capture plant.
대표청구항▼
The invention claimed is: 1. Method for increasing energy and cost efficiency of a combined cycle gas turbine power plant and for energy and cost effective CO2 capture from a pressurized CO2 enriched flue gas, the method comprising: at least one of providing and operating a gas turbine power plant
The invention claimed is: 1. Method for increasing energy and cost efficiency of a combined cycle gas turbine power plant and for energy and cost effective CO2 capture from a pressurized CO2 enriched flue gas, the method comprising: at least one of providing and operating a gas turbine power plant comprising one or more gas turbine plants and/or a combined plant of steam and gas turbine cycles, comprising one or more compressor units and one or more turbines and further comprising a combustor; cooling flue gas from the combustor and passing the flue gas through a cleaning unit, the method further including removing at least substantial portions of CO2 content from the flue gas to obtain cleaned flue gas and reheating the cleaned flue gas and, together with pressurized steams, driving the one or more turbines, and depressurizing the steam prior to being discharged to atmosphere; and operating the combustor such that the combustor is working with two completely separate gas part streams, one of the two gas part streams being kept completely isolated from the innards of a flame tube of the combustor, wherein a first gas part stream is directed internally in the flame tube of the combustor and wherein a second gas part stream passes along an exterior of the flame tube, the first gas part stream comprising additional air and re-circulated un-cleaned flue gas from the combustor which is combusted together with fuel inside the flame tube, and the second gas part stream comprising cleaned flue gas which is heated by the exterior of the flame tube while the flame tube is being cooled. 2. Method according to claim 1, wherein the method further comprises: at least one of operating and providing the power plant such that the power plant has a first gas turbine and a second gas turbine, each having a respective compressor unit and a respective turbine unit, the un-cleaned flue gas from the combustor being compressed in the compressor unit of the second gas turbine, the second gas part stream being cleaned and used for heat exchange in the combustor in order to obtain optimal heating of the second gas part stream in the combustor; and transferring the heat energy at a highest possible temperature and wherein the cleaned gas part stream then is fed to an inlet of the turbine unit of the first gas turbine for driving said first gas turbine plant. 3. Method according to claim 1, wherein a pressurized part of the flue gas to be cleaned is led through a CO2 capture unit in order to remove CO2 from the flue gas. 4. Method according to claim 1, wherein steam is injected in the second gas part stream before the inlet of a jacket surrounding the flame tube of the combustor, in order to compensate for removed CO2 in a CO2 capture unit and in order to enhance heat transfer in the combustor. 5. Method according to claim 4, wherein the second gas part stream having traveled from the compressor is fed into the jacket at an exit of the combustor and exits the jacket in an area of the combustion zone of the combustor. 6. Method according to claim 1, wherein the first gas part stream having travelled from the compressor unit is re-circulated back to the flame tube together with pressurized air and fuel. 7. Method according to claim 1, wherein flue gas pressure is increased after expansion and cooling and wherein a portion of the first gas part stream is re-circulated back to the combustor in order to optimize enrichment of CO2 prior to entering a CO2 capture unit. 8. Method according to claim 1, wherein water is removed from the flue gas in front of a booster, pressurizing the flue gas, whereupon water is added again after passing through the booster, thereby regulating a mole weight of flue gas at the inlet to a compressor. 9. Method according to claim 1, wherein the flue gas is fed through a heat recovery steam generator for production of steam, wherein at least a portion of the produced steam is fed back to the second gas stream in front of a jacket of the combustor. 10. Method according to claim 9, wherein the remaining parts of the produced steam drive one or more steam turbines. 11. Method according to claim 1, wherein one part of the flue gas is fed via a heat exchanger to the CO2 capture plant whereupon the cleaned flue gas is returned back via the heat exchanger where it is reheated and mixed with steam and additional air from a compressor unit, forming the second gas part stream flowing along the exterior of the flame tube. 12. Method according to claim 1, wherein a first and second gas turbine plant, being coupled in series, are used and having one or more common combustors, the method including heating gas at an exterior of the flame tube and feeding the heated gas through a unit for adding heat, and feeding the heated gas to the turbine unit of the first gas turbine plant, and the flue gas formed in the flame tube is fed to the turbine unit of the second gas turbine plant, whereupon the flue gas is fed to a heat recovery steam generator where the flue gas is cooled and thereafter led via a water cooler to the inlet of a compressor of the second gas turbine plant where the flue gas is compressed and split into two flue gas part streams. 13. Method according to claim 12, wherein one flue gas stream is led via a heat exchanger to a CO2 capture plant whereupon the cleaned flue gas is fed back via the heat exchanger where the flue gas is reheated and then mixed with steam and thereafter circulated around the exterior of the flame tube. 14. A method of operating a power plant, the method comprising: operating a first combined cycle gas turbine power plant, wherein the action of operating the first combined cycle gas turbine power plant includes: directing a first gas stream into a flame tube of a combustor of the plant and combusting the first gas stream with fuel inside the flame tube to produce flue gas, the first gas stream including additional air and re-circulated un-cleaned flue gas; directing a second gas stream that includes a portion of the produced flue gas from the combustor through a cleaning unit and cleaning the flue gas, wherein the action of cleaning the flue gas includes removing CO2 from the flue gas, to obtain cleaned flue gas; directing the second gas stream about an exterior of the flame tube of the combustor while the first gas stream is being directed into the flame tube, wherein the second gas stream is completely separate from the first gas stream and is kept completely isolated from the interior of the flame tube, the action of directing the second gas stream about the exterior of the flame tube resulting in heat transfer from the first gas stream to the second gas stream, through the flame tube; and driving one or more turbines utilizing, at least in part, the cleaned flue gas. 15. Method according to claim 14, wherein the method includes simultaneously operating a second combined cycle gas turbine power plant which is connected to the first combined cycle gas turbine power plant, the second combined gas turbine plant being driven by the un-cleaned flue gas while the first combined cycle gas turbine power plant is driven by the cleaned flue gas. 16. Method according to claim 14, wherein the action of directing a portion of the flue gas to the cleaning unit includes directing the portion of the flue gas to the cleaning unit such that the flue gas has, upon entry into the cleaning unit, a pressure of at least 15 bar and a content of CO2 exceeding 10%. 17. Method according to claim 14, wherein a temperature of the flue gas, upon leaving the combustor, is about 1200-1400�� C. 18. Method according to claim 14, wherein a temperature of the flue gas, upon leaving the combustor, is about 1200-1400�� C. 19. Method according to claim 14, wherein the combustor operates as a heat exchanger to cool the flue gas. 20. Method according to claim 15, wherein the first and second combined cycle gas turbine power plants are coupled in series and share at least one common combustor, the method further including: heating gas at an exterior of the flame tube and feeding the heated gas through a unit to add thermal energy to the gas, thereby obtaining heated gas; feeding the heated gas to a turbine unit of the first combined cycle gas turbine power plant; feeding the flue gas formed in the flame tube being to a turbine unit of the second combined cycle gas turbine plant; and feeding the flue gas from the turbine unit of the second combined cycle gas turbine plant to a heat recovery steam generator where the flue gas is cooled and thereafter led via a water cooler to the inlet of a compressor of the second combined cycle gas turbine plant where the flue gas is compressed and split into two the two completely separate gas part streams.
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