A unique, small microturbine engine adapted to integrate with an electrical generator for producing electrical power has been developed. The microturbine includes an ejector cooling scheme, a prevaporizing combustor, and a combustor air bypass. The ejector cooling scheme uses energy in the hot exhau
A unique, small microturbine engine adapted to integrate with an electrical generator for producing electrical power has been developed. The microturbine includes an ejector cooling scheme, a prevaporizing combustor, and a combustor air bypass. The ejector cooling scheme uses energy in the hot exhaust gas stream of the microturbine to entrain a flow of ambient air that cools the generator. The prevaporizing combustor of the present invention allows liquid fuel to be vaporized in a small amount of air prior to combustion, thereby increasing combustion efficiency and decreasing combustor size requirements. The combustor air bypass allows a fraction of the compressor discharge air to bypass the prevaporizing combustor under certain operating conditions. This permits control of the overall equivalence ratio and the fuel/air mixing process in the combustion zone, improving efficiency and operability.
대표청구항▼
1. A microturbine for powering a generator comprising: a. a centrifugal compressor comprising a compressor rotor, a diffuser and a volute to provide a continuous flow of compressed air;b. a prevaporizing combustor for mixing the compressed air with fuel, wherein the compressed air is mixed with fuel
1. A microturbine for powering a generator comprising: a. a centrifugal compressor comprising a compressor rotor, a diffuser and a volute to provide a continuous flow of compressed air;b. a prevaporizing combustor for mixing the compressed air with fuel, wherein the compressed air is mixed with fuel in a specific ratio to produce a high-pressure hot gas, the prevaporizing combustor having an exit opening, wherein the prevaporizing combustor comprises: i. a prevaporizing zone for mixing compressed air and fuel to an air/fuel mixture, wherein the prevaporizing zone includes a first compressed air channel and a second fuel channel, andii. a combustion zone wherein the combustion zone includes a compressed air channel for receiving compressed air, the combustion zone comprising: 1. a primary zone for mixing the air/fuel mixture from the prevaporizing zone with compressed air in the combustion zone to produce a combustion product, and2. a dilution zone for receiving and cooling the combustion product of the primary zone;c. a combustor air bypass to control the compressed air from the centrifugal compressor, the combustor air bypass comprising a duct connecting the centrifugal compressor with the exit opening of the prevaporizing combustor;d. a radial inflow compressor turbine to extract power from the high-pressure hot gas; ande. an axial free power turbine to extract power from the high-pressure hot gas. 2. The microturbine of claim 1, further comprising an exhaust heat exchanger to preheat the fuel. 3. The microturbine of claim 1, further comprising a supplemental electric fuel heater to preheat the fuel. 4. The microturbine of claim 1 wherein the prevaporizing zone further includes a tangential-entry swirler including a plurality of air inlet jets. 5. The microturbine of claim 1 wherein the primary zone comprises: a. a liner wall containing openings for air flow,b. a splash ring and effusion cooling holes to produce an insulating film of air to flow along the liner wall, andc. an igniter to initiate a reaction of combustion gases. 6. The microturbine of claim 5 wherein the dilution zone comprises a liner wall containing openings for air flow to reduce the temperature of combustion gases. 7. The microturbine of claim 1 further comprising: a. a housing;b. a first rotatable shaft mounted through the housing, the first rotatable shaft having a first end and a second hot exhaust end, wherein the compressor is mounted to the first end of the rotatable shaft and wherein the radial inflow compressor turbine is mounted to the second end of the rotatable shaft, and wherein the radial inflow compressor turbine receives the high-pressure hot gas produced from the prevaporizing combustor thereby causing the microturbine rotatable shaft to rotate;c. a second rotatable power output shaft having a first end and a second end, wherein the axial free power turbine is mounted to the first end of the second power output shaft to extract power from the high-pressure hot gas. 8. The microturbine of claim 7 further comprising: a. an electric generator having a stator installed in the housing and a rotor fixed to the second power output shaft so as to be rotated together; andb. an generator cooling system to provide cooling air to the generator, the system comprising: i. a passage surrounding the generator, the passage having a first end and a second end, wherein the first end is open to the atmosphere and the second end is open to the discharge area of the second end of the axial free power turbine to create a cool air draw from the first end of the passage to the second end of the passage, andii. an exhaust diffuser for expelling air along with microturbine discharge gas. 9. A microturbine for powering a generator comprising: a. a housing;b. a first rotatable shaft mounted through the housing, the rotatable shaft having a first end and a second hot exhaust end;c. a second power output shaft;d. a centrifugal compressor comprising a compressor rotor, a diffuser and a volute to provide a continuous flow of compressed air;e. a prevaporizing combustor for mixing the compressed air with fuel, wherein the compressed air is mixed with fuel to produce a high-pressure hot gas, wherein the centrifugal compressor is mounted to the first end of the rotatable shaft and wherein the radial inflow compressor turbine is mounted to the second end of the rotatable shaft and receives the high-pressure hot gas produced from the prevaporizing combustor thereby causing the microturbine rotatable shaft to rotate, wherein the prevaporizing combustor includes an exit opening;f. a combustor air bypass to control the compressed air from the centrifugal compressor, the combustor air bypass comprising a duct connecting the centrifugal compressor with the exit opening in the prevaporizing combustor;g. a radial inflow compressor turbine to extract power from the high-pressure hot gas;h. an axial free power turbine to extract power from the high-pressure hot gas;i. a generator having a stator installed in the housing and a rotor fixed to the second power output shaft so as to be rotated together; andj. a generator cooling system to provide cooling air to the generator, the system comprising: i. a passage surrounding the generator, the passage having a first end and a second end, wherein the first end is open to the atmosphere and the second end is open to the discharge area of the axial free power turbine to create a cool air draw from the first end of the passage to the second end of the passage, andii. an exhaust diffuser for pumping and expelling air from the generator along with microturbine discharge gas. 10. The microturbine of claim 9, wherein the prevaporizing combustor comprises: a. a prevaporizing zone for mixing compressed air and fuel to an air/fuel mixture, wherein the prevaporizing zone includes a first compressed air channel and a second fuel channel, andb. a combustion zone wherein the combustion zone includes a compressed air channel for receiving compressed air, the combustion zone comprising: i. a primary zone for mixing the air/fuel mixture from the prevaporizing zone with compressed air in the combustion zone to produce a combustion product, wherein the primary zone comprises: 1. a liner wall containing openings for air flow,2. a splash ring and effusion cooling holes to produce an insulating film of air to flow along the liner wall, and3. an igniter to initiate a reaction of combustion gases, andii. a dilution zone for receiving the combustion product of the primary zone, wherein the dilution zone comprises a liner wall containing openings for air flow to reduce the temperature of combustion gases. 11. The microturbine of claim 9, further comprising an exhaust heat exchanger to preheat the fuel. 12. The microturbine of claim 9, further comprising a supplemental electric fuel heater to preheat the fuel. 13. The microturbine of claim 9 wherein the prevaporizing zone further includes a tangential-entry swirler including a plurality of air inlet jets. 14. The microturbine of claim 9 further comprising: a. a housing;b. a first rotatable shaft mounted through the housing, the first rotatable shaft having a first end and a second hot exhaust end, wherein the compressor is mounted to the first end of the rotatable shaft and wherein the radial inflow compressor turbine is mounted to the second end of the rotatable shaft, and wherein the radial inflow compressor turbine receives the high-pressure hot gas produced from the prevaporizing combustor thereby causing the microturbine rotatable shaft to rotate;c. a second rotatable power output shaft having a first end and a second end, wherein the axial free power turbine is mounted to the first end of the second power output shaft to extract power from the high-pressure hot gas; andd. a plurality of bearings for supporting the first rotatable shaft and second rotatable power output shaft. 15. A microturbine for powering a generator comprising: a. a housing;b. a first rotatable shaft mounted through the housing, the rotatable shaft having a first end and a second hot exhaust end;c. a second power output shaft;d. a centrifugal compressor comprising a compressor rotor, a diffuser and a volute to provide a continuous flow of compressed air;e. a prevaporizing combustor for mixing the compressed air with fuel, wherein the compressed air is mixed with fuel in small, measured amounts to produce a high-pressure hot gas, wherein the compressor is mounted to the first end of the rotatable shaft and wherein the radial inflow compressor turbine is mounted to the second end of the rotatable shaft and receives the high-pressure hot gas produced from the prevaporizing combustor thereby causing the microturbine rotatable shaft to rotate, and wherein the prevaporizing combustor comprises: i. a prevaporizing zone for mixing compressed air and fuel to an air/fuel mixture, wherein the prevaporizing zone includes a first compressed air channel and a second fuel channel, andii. a combustion zone wherein the combustion zone includes a compressed air channel for receiving compressed air, the combustion zone comprising: 1. a primary zone for mixing the air/fuel mixture from the prevaporizing zone with compressed air in the combustion zone to produce a combustion product, wherein the primary zone comprises: a. a liner wall containing openings for air flow,b. a splash ring and effusion cooling holes to produce an insulating film of air to flow along the liner wall, andc. an igniter to initiate a reaction of combustion gases, and2. a dilution zone for receiving the combustion product of the primary zone, wherein the dilution zone comprises a liner wall containing openings for air flow to reduce the temperature of combustion gases;f. a combustor air bypass to control the compressed air from the centrifugal compressor, the combustor air bypass comprising a duct connecting the centrifugal compressor with the prevaporizing combustor;g. a radial inflow compressor turbine to extract power from the high-pressure hot gas;h. an axial free power turbine to extract power from the high-pressure hot gas;i. a generator having a stator installed in the housing and a rotor fixed to the second power output shaft so as to be rotated together; andj. a generator cooling system to provide cooling air to the generator, the system comprising: i. a passage surrounding the generator, the passage having a first end and a second end, wherein the first end is open to the atmosphere and the second end is open to the discharge area of the axial free power turbine to create a cool air draw from the first end of the passage to the second end of the passage, andii. an exhaust diffuser for expelling air along with microturbine discharge gas. 16. The microturbine of claim 15, further comprising an exhaust heat exchanger to preheat the fuel. 17. The microturbine of claim 15, further comprising a supplemental electric fuel heater to preheat the fuel. 18. The microturbine of claim 15 wherein the prevaporizing zone further a tangential-entry swirler including a plurality of air inlet jets. 19. The microturbine of claim 15 further comprising: a. a housing;b. a first rotatable shaft mounted through the housing, the first rotatable shaft having a first end and a second hot exhaust end, wherein the compressor is mounted to the first end of the rotatable shaft and wherein the radial inflow compressor turbine is mounted to the second end of the rotatable shaft, and wherein the radial inflow compressor turbine receives the high-pressure hot gas produced from the prevaporizing combustor thereby causing the microturbine rotatable shaft to rotate;c. a second rotatable power output shaft having a first end and a second end, wherein the axial free power turbine is mounted to the first end of the second power output shaft to extract power from the high-pressure hot gas; andd. a plurality of bearings for supporting the first rotatable shaft and second rotatable power output shaft.
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