A cyclonic combustor comprising a combustion liner forming a combustion chamber having a generally cylindrical shape, a biomass feed inlet for receiving biomass particles under pressure, wherein the biomass feed inlet is formed so that the biomass particles are introduced into the ignition zone of t
A cyclonic combustor comprising a combustion liner forming a combustion chamber having a generally cylindrical shape, a biomass feed inlet for receiving biomass particles under pressure, wherein the biomass feed inlet is formed so that the biomass particles are introduced into the ignition zone of the combustion chamber with a tangential component relative to the longitudinal axis of the combustion liner, and a plurality of air tuyeres formed through the combustion liner for receiving compressed air, wherein the plurality of air tuyeres are arranged to introduce the compressed air into the combustion chamber with a tangential component relative to the longitudinal axis of the combustion liner. A direct-fired biomass-fueled pressurized gas turbine system comprising a pressurized feed system, the cyclonic combustor, and a gas turbine. Methods of operating a cyclonic combustor and methods for direct firing a gas turbine.
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1. A cyclonic combustor comprising: a combustion liner forming a combustion chamber having a generally cylindrical shape and operable to have an ignition zone, a combustion zone, and a dilution zone arranged longitudinally along the axis of the combustion chamber;a biomass feed inlet at one end of t
1. A cyclonic combustor comprising: a combustion liner forming a combustion chamber having a generally cylindrical shape and operable to have an ignition zone, a combustion zone, and a dilution zone arranged longitudinally along the axis of the combustion chamber;a biomass feed inlet at one end of the combustion chamber formed through the combustion liner for receiving biomass particles under pressure, wherein the biomass feed inlet is formed so that the biomass particles are introduced into the ignition zone of the combustion chamber with a tangential component relative to the longitudinal axis of the combustion liner;a plurality of air tuyeres formed through the combustion liner for receiving compressed air, wherein the plurality of air tuyeres are arranged to introduce the compressed air into the combustion chamber with a tangential component relative to the longitudinal axis of the combustion liner, wherein the plurality of air tuyeres are spaced along the length of the combustion liner from about the biomass feed inlet,wherein at least one of the plurality of air tuyeres is operable to supply a sufficient amount of compressed air to the ignition zone for ignition of the biomass particles to begin the combustion, wherein at least one of the plurality of air tuyeres is operable to supply a sufficient amount of compressed air to the combustion zone to complete the combustion of the biomass particles from the ignition zone, andwherein at least one other of the plurality of air tuyeres is operable to supply a sufficient amount of compressed air to the dilution zone to dilute the combustion gas to a temperature suitable for use in a gas turbine;an outer casing having a generally cylindrical shape and surrounding the combustion liner;an inner lining having a generally cylindrical shape and surrounding the combustion liner so as to define at least two air plenums between the outer casing and the combustion liner wherein the at least two air plenums are in communication with the combustion chamber via the plurality of air tuyeres so that the compressed air is supplied to the combustion chamber through the at least two air plenums; and wherein the outer casing surrounds the intermediate liner so as to define a cooling plenum between the outer casing and the intermediate liner, wherein the cooling plenum is in communication with the at least two air plenums so that the compressed air is supplied to the air plenums via the cooling plenum. 2. The cyclonic combustor of claim 1 further comprising a cyclonic ash separator comprising: a choke element comprising an opening of reduced cross-section area as compared to the cross-sectional area of the combustion chamber, an input in communication with the combustion chamber outlet for receiving the combustion gas from the combustion and dilution zone chamber, and an output in communication with the turbine section of the gas turbine for supplying the gas turbine with the combustion gas; anda particulate ash opening defined between the choke element and the combustion liner wherein at least a portion of the particulate ash exits the combustion chamber via the particulate ash opening. 3. The cyclonic combustor of claim 1 wherein the cyclonic ash separator comprises an input in communication with the combustion chamber outlet for receiving a mixture of the combustion gas and particulate ash, wherein the cyclonic ash separator at least partially separates the combustion gas from the particulate ash and further comprises an outlet in communication with the turbine section of the gas turbine for supplying the gas turbine with the combustion gas. 4. The cyclonic combustor of claim 1 wherein a sub-stoichiometric amount of compressed air is supplied to the ignition zone. 5. The cyclonic combustor of claim 1 wherein the plurality of tuyeres increase in size along the length of the longitudinal axis of the combustion liner. 6. The cyclonic combustor of claim 1 wherein the plurality of tuyeres are arranged in a plurality of rows spaced along the length of the longitudinal axis of the combustion liner, wherein each row contains at least one tuyere distributed along the same plane. 7. The cyclonic combustor of claim 6 wherein the at least one air tuyere in one or more of the plurality of rows is displaced about 90 degrees along the circumference of the combustion liner with respect to the preceding row. 8. The cyclonic combustor of claim 6 wherein the at least one air tuyere in one or more of the plurality of rows is larger than the at least one air tuyere in the combustion liner with respect to the preceding row. 9. The cyclonic combustor of claim 1 comprising a transition assembly comprising an inner lining that forms a combustion gas passageway, the combustion gas passageway comprising an inlet in communication with the output of the choke element for receiving the combustion gas, and an outlet in communication with the gas turbine for supplying the gas turbine with the combustion gas. 10. The cyclonic combustor of claim 9 wherein the combustion gas passageway has a smaller cross sectional area at the outlet than at the inlet. 11. The cyclonic combustor of claim 2 wherein a burner is connected to the cyclonic combustor. 12. A direct-fired biomass-fueled pressurized gas turbine system comprising: a pressurized feed system;a cyclonic combustor, comprising: a combustion liner forming a combustion chamber having a generally cylindrical shape and operable to have an ignition zone, a combustion zone, and a dilution zone arranged longitudinally along the axis of the combustion chamber;a biomass feed inlet at one end of the combustion chamber formed through the combustion liner for receiving biomass particles under pressure, wherein the biomass feed inlet is formed so that the biomass particles are introduced into the ignition zone of the combustion chamber with a tangential component relative to the longitudinal axis of the combustion liner;a plurality of air tuyeres formed through the combustion liner for receiving compressed air, wherein the plurality of air tuyeres are arranged to introduce the compressed air into the combustion chamber with a tangential component relative to the longitudinal axis of the combustion liner, wherein the plurality of air tuyeres are spaced along the length of the combustion liner from about the biomass feed inlet,wherein at least one of the plurality of air tuyeres is operable to supply a sufficient amount of compressed air to the ignition zone for ignition of the biomass particles to begin the combustion,wherein at least one of the plurality of air tuyeres is operable to supply a sufficient amount of compressed air to the combustion zone to complete the combustion of the biomass particles from the ignition zone, andwherein at least one other of the plurality of air tuyeres is operable to supply a sufficient amount of compressed air to the dilution zone to dilute the combustion gas to a temperature suitable for use in a gas turbine;an outer casing having a generally cylindrical shape and surrounding the combustion liner; andan inner lining having a generally cylindrical shape and surrounding the combustion liner so as to define at least two air plenums between the outer casing and the combustion liner wherein the at least two air plenums are in communication with the combustion chamber via the plurality of air tuyeres so that the compressed air is supplied to the combustion chamber through the at least two air plenums; and wherein the outer casing surrounds the intermediate liner so as to define a cooling plenum between the outer casing and the intermediate liner, wherein the cooling plenum is in communication with the at least two air plenums so that the compressed air is supplied to the air plenums via the cooling plenum;a gas turbine comprising: a turbine section comprising an inlet in communication with the combustor for receiving the combustion gas from the combustion chamber, wherein the turbine section is driven by the combustion gas. 13. The system of claim 12 wherein the pressurized feed system comprises: a plurality of chambers; wherein a first chamber receives biomass particles at atmospheric pressure and supplies a second chamber with biomass particles under pressure;a first valve positioned at an inlet of the first chamber;a second valve positioned at an outlet of the first chamber communicating with the inlet to the second chamber; andan air compressor arranged to pressurize the first chamber. 14. The system of claim 13 wherein the first valve and the second valve are slide gate valves. 15. The system of claim 12 wherein the pressurized feed system further comprises a rotary valve arranged to feed variable amounts of biomass particles to the combustion chamber. 16. The system of claim 12 wherein each of the at least two air plenums are in communication with a corresponding compressed air feed; wherein the corresponding compressed air feed comprises a valve for controlling the supply of the compressed air to the combustion chamber through the air plenum that is in communication with the valve. 17. The system of claim 12 wherein the gas turbine further comprises a compressor section driven by the turbine section of the gas turbine, wherein the compressor section is arranged to provide the compressed air to the combustion chamber. 18. The system of claim 17 wherein a first portion of the compressed air from the compressor section is supplied to the combustion chamber, and a second portion of the compressed air conveys the biomass particles from the pressurized feed system to the combustion chamber. 19. The system of claim 12 comprising a heat exchanger for cooling the second portion of the compressed air from the compressor section. 20. The system of claim 12 wherein the gas turbine has a pressure ratio in the range of from 8:1 to 20:1. 21. The system of claim 12 further comprising an electric generator coupled to the gas turbine for generating electric power, wherein the electric generator is driven by the turbine section of the gas turbine. 22. The system of claim 21 wherein the system is constructed and arranged to generate less than 10 megawatts of electricity. 23. The system of claim 21 wherein the gas turbine comprises a single shaft that drives the compressor section and the electric generator. 24. The system of claim 12 wherein the direct-fired biomass-fueled pressurized gas turbine system further comprises a heat recovery unit in communication with an exhaust stream from the turbine section of the gas turbine. 25. The system of claim 12 further comprising a fuel input system for providing sized and dried biomass particles to the pressurized feed system. 26. The system of claim 12 further comprising a second air compressor arranged to supply compressed air that conveys the biomass particles from the pressurized feed system to the combustion chamber.
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