A method for the generation of electrical power from a carbonaceous fuel, wherein the fuel is combusted in presence of oxygen under increased pressure in a combustion chamber is described. The exhaust gas from the combustion is separated into a CO2 rich fraction that is handled so that it does not e
A method for the generation of electrical power from a carbonaceous fuel, wherein the fuel is combusted in presence of oxygen under increased pressure in a combustion chamber is described. The exhaust gas from the combustion is separated into a CO2 rich fraction that is handled so that it does not escape to the surroundings, and a CO2 depleted fraction that is expanded over one or more turbines to power other processes and/or generation of electrical power, before the gas is released into the surroundings, where the temperature in the combustion chamber is reduced under the generation of steam that is expanded over steam turbines connected to electrical generator for the generation of electrical power. Additionally a thermal power plant for the performing of the method is described.
대표청구항▼
The invention claimed is: 1. A method for generation of electric energy from a carbonaceous fuel, comprising the steps of: combusting the fuel in the presence of oxygen under elevated pressure in a combustion chamber; generating steam in the combustion chamber to reduce the temperature therein; wit
The invention claimed is: 1. A method for generation of electric energy from a carbonaceous fuel, comprising the steps of: combusting the fuel in the presence of oxygen under elevated pressure in a combustion chamber; generating steam in the combustion chamber to reduce the temperature therein; withdrawing an exhaust gas from the combustion chamber; separating the exhaust gas from the combustion chamber into a CO2 rich fraction and a CO2 depleted fraction; treating the CO2 rich fraction so that it does not escape to the surroundings; expanding the CO2 depleted fraction over one or more turbines for operation of other processes and/or generation of electric energy; and releasing the CO2 depleted fraction into the surroundings. 2. The method according to claim 1, wherein more than 50% of the heat energy from the combustion in the combustion chamber is used to produce steam in the combustion chamber. 3. The method according to claim 1 or 2, further comprising the step of heat exchanging the exhaust gas from the combustion chamber against the CO2 depleted fraction, for cooling of the exhaust gas and heating of the CO2 depleted fraction before the CO2 depleted fraction is expanded over turbines. 4. The method according to claim 3, further comprising the step of adding water and/or air to the CO2 depleted fraction to increase the ability of the CO2 depleted fraction to take up heat from the hot exhaust gas from the combustion chamber. 5. The method according to claim 1, further comprising the step of heating the fuel before it is fed to the combustion chamber. 6. The method according to claim 5, further comprising the steps of: heating the fuel by heat exchanging against a part stream from an air compressor; and supplying the heat exchanged and thus cooled air stream to the CO2 depleted fraction to increase the heat capacity thereof. 7. A thermal power station for carbonaceous fuel, comprising: a combustion chamber, where the fuel is burned under elevated pressure in the presence of oxygen; a gas pipe for leading an exhaust gas from the combustion chamber through cooling means into a contact device where the exhaust gas is brought into contact with an absorption agent in which mainly CO2 is absorbed and where the other gases in the exhaust gas, in the main, are not absorbed; a gas pipe for withdrawal of a not absorbed or CO2 depleted fraction, from the contact device; means to reheat the CO2 depleted fraction; means for expansion of the reheated CO2 depleted fraction before releasing the expanded CO2 depleted fraction into the surroundings; and means to transport the absorption agent with absorbed CO2 from the contact device to deposition or to means for regeneration of the absorption agent for re-circulation to the contact device, wherein the combustion chamber comprises means to provide steam and lines to lead the steam to steam turbines for expansion of the steam. 8. The thermal power plant according to claim 7, further comprising a condensation chamber for condensation of water in the exhaust gas arranged before the contact device. 9. The thermal power plant according to claim 8, further comprising means to add the water which has condensed in the condensation chamber to the CO2 depleted fraction to increase the heat capacity of the CO2 depleted fraction. 10. The thermal power plant according to claim 7 or 8, wherein the combustion chamber comprises: an outer shell and an inner shell between which flows a cooling medium and where pipes, that cover the inner surface of the combustion chamber, are arranged; and means to circulate water through the pipes. 11. The method according to claim 1, wherein more than 60% of the heat energy from the combustion in the combustion chamber is used to produce steam in the combustion chamber. 12. The method according to claim 1, wherein more than 70% of the heat energy from the combustion in the combustion chamber is used to produce steam in the combustion chamber. 13. The method according to claim 11 or 12, wherein the exhaust gas from the combustion chamber is cooled by heat exchange with the CO2 depleted fraction for heating of the CO2 depleted fraction before the CO2 depleted fraction is expanded over turbines. 14. The method according to claim 13, wherein water and/or air is added to the CO2 depleted fraction to increase the ability of the CO2 depleted fraction to take up heat from the hot exhaust gas from the combustion chamber. 15. The thermal power plant according to claim 7, wherein a heat exchanger is provided on an inlet line of the fuel to heat the fuel before it is introduced into the combustion chamber. 16. A thermal power station for carbonaceous fuel, comprising: a combustion chamber, where the fuel is burned under elevated pressure in the presence of oxygen; a gas pipe for leading an exhaust gas from the combustion chamber through a cooling device into a contact device where the exhaust gas is brought into contact with an absorption agent in which mainly CO2 is absorbed and where the other gases in the exhaust gas, in the main, are not absorbed; a gas pipe for withdrawal of a not absorbed or CO2 depleted fraction, from the contact device; a reheating device that reheats the CO2 depleted fraction; an expansion device that expands the reheated CO2 depleted fraction before releasing the CO2 depleted fraction into the surroundings; and a transporting device that transports the absorption agent with absorbed CO2 from the contact device to deposition or to a regeneration device that regenerates the absorption agent for re-circulation to the contact device, wherein the combustion chamber comprises a device to provide steam and lines to lead the steam to steam turbines for expansion of the steam. 17. The thermal power plant according to claim 16, further comprising a condensation chamber for condensation of water in the exhaust gas arranged before the contact device. 18. The thermal power plant according to claim 17, further comprising a device that adds the water which has condensed in the condensation chamber to the CO2 depleted fraction to increase the heat capacity of the CO2 depleted fraction. 19. The thermal power plant according to claim 16 or 17, wherein the combustion chamber comprises: an outer shell and an inner shell between which flows a cooling medium and where pipes, that cover the inner surface of the combustion chamber, are arranged; and a circulation device to circulate water through the pipes. 20. The thermal power plant according to claim 16, wherein a heat exchanger is provided on an inlet line of the fuel to heat the fuel before it is introduced into the combustion chamber.
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이 특허에 인용된 특허 (3)
Osgerby Ian (c/o Dennis R. Lowe ; Esq. ; 1842 Massachusetts Ave. Lexington MA 02173), Carbon dioxide power cycle.
Palmer, Miles; Allam, Rodney John; Fetvedt, Jeremy Eron; Freed, David Arthur; Brown, Jr., Glenn William, Method of using carbon dioxide in recovery of formation deposits.
Allam, Rodney John; Forrest, Brock Alan; Fetvedt, Jeremy Eron, Production of low pressure liquid carbon dioxide from a power production system and method.
Allam, Rodney John; Brown, Jr., Glenn William; Palmer, Miles R., System and method for high efficiency power generation using a carbon dioxide circulating working fluid.
Allam, Rodney John; Brown, Jr., Glenn William; Palmer, Miles R., System and method for high efficiency power generation using a carbon dioxide circulating working fluid.
Allam, Rodney John; Palmer, Miles R.; Brown, Jr., Glenn William, System and method for high efficiency power generation using a carbon dioxide circulating working fluid.
Allam, Rodney John; Palmer, Miles R.; Brown, Jr., Glenn William, System and method for high efficiency power generation using a carbon dioxide circulating working fluid.
Allam, Rodney John; Palmer, Miles R.; Brown, Jr., Glenn William; Fetvedt, Jeremy Eron; Forrest, Brock Alan, System and method for high efficiency power generation using a carbon dioxide circulating working fluid.
Allam, Rodney John; Palmer, Miles; Brown, Jr., Glenn William, System and method for high efficiency power generation using a carbon dioxide circulating working fluid.
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