Described herein are embodiments of systems and methods for oxidizing gases. In some embodiments, a reaction chamber is configured to receive a fuel gas and maintain the gas at a temperature within the reaction chamber that is above an autoignition temperature of the gas. The reaction chamber may al
Described herein are embodiments of systems and methods for oxidizing gases. In some embodiments, a reaction chamber is configured to receive a fuel gas and maintain the gas at a temperature within the reaction chamber that is above an autoignition temperature of the gas. The reaction chamber may also be configured to maintain a reaction temperature within the reaction chamber below a flameout temperature. In some embodiments, heat and product gases from the oxidation process can be used, for example, to drive a turbine, reciprocating engine, and injected back into the reaction chamber.
대표청구항▼
1. An oxidizer for oxidizing fuel, comprising: a reaction chamber having (i) one or more inlets that are configured to direct at least one gas of a fuel, oxidant, or diluent, into the reaction chamber and (ii) one or more outlets that are configured to direct reaction products from the reaction cham
1. An oxidizer for oxidizing fuel, comprising: a reaction chamber having (i) one or more inlets that are configured to direct at least one gas of a fuel, oxidant, or diluent, into the reaction chamber and (ii) one or more outlets that are configured to direct reaction products from the reaction chamber;a regulator that is configured to maintain a temperature of one or more of the at least one gas, at or before the one or more inlets, to be below an autoignition temperature of a resulting mixture within the reaction chamber that comprises the at least one gas of fuel, oxidants, or diluents; anda heat exchanger, positioned within the reaction chamber, configured to heat the incoming resulting mixture at or near the one or more inlets, such that a temperature of the resulting mixture inside the reaction chamber is increased above the autoignition temperature;a heat extractor that removes heat from the reaction chamber after the mixture inside the reaction chamber is increased above the autoignition temperature; anda controller, comprising: a detection module that detects when a reaction temperature within the reaction chamber exceeds a flameout temperature of the mixture; anda correction module that outputs instructions, based on the detection module, to the heat extractor to increase a removal of heat from the reaction chamber to maintain an adiabatic temperature within the reaction chamber below the flameout temperature of the mixture and a maximum reaction temperature within the reaction chamber below the flameout temperature of the mixture. 2. The oxidizer of claim 1, wherein the reaction chamber comprises a single inlet. 3. The oxidizer of claim 1, wherein the oxidizer is configured to change a flow rate that the mixture is introduced into the reaction chamber through the one or more inlets. 4. The oxidizer of claim 1, wherein the oxidizer is configured to change a flow rate that one or more of the at least one gas of fuel, oxidants, or diluents is introduced into the reaction chamber through the one or more inlets. 5. The oxidizer of claim 1, further comprising a heater that transfers heat from the reaction products to the mixture at or before the one or more inlets. 6. The oxidizer of claim 1, wherein the regulator is configured to mix diluents with fuel at or before the one or more inlets. 7. The oxidizer of claim 1, wherein the oxidizer is configured to use heat from the reaction products to generate steam. 8. The oxidizer of claim 1, wherein the oxidizer is configured to use heat from the reaction products to drive a generator for power generation. 9. The oxidizer of claim 8, wherein the oxidizer is configured to drive a generator by a turbine or a piston engine that is configured to expand the reaction products from the reaction chamber. 10. The oxidizer of claim 1, wherein the oxidizer is configured to use heat from the reaction products to heat material that is not passed through the oxidizer. 11. The oxidizer of claim 1, wherein the oxidizer is configured to change a flow rate that the reaction products are directed from the reaction chamber through the one or more outlets. 12. The oxidizer of claim 1, further comprising a controller that is configured to change at least one of a flow of the mixture or a pressure of the mixture at or near the one or more inlets. 13. The oxidizer of claim 1, further comprising a controller that is configured to change at least one of a temperature, a flow rate, or a pressure of at least one of a fuel, oxidant, or diluent at or near one or more inlets. 14. An oxidizer for oxidizing fuel, comprising: a reaction chamber having (i) an inlet that is configured to direct at least one gas of fuel, oxidants, or diluents, into the reaction chamber and (ii) an outlet that is configured to direct reaction products from the reaction chamber;means for maintaining a temperature of the incoming gas, at or before the inlet, to below an autoignition temperature of a resulting mixture within the reaction chamber that comprises the at least one gas of fuel, oxidants, or diluents;a heat exchanger, positioned within the reaction chamber, configured to heat the incoming resulting mixture at or near the inlet, such that a temperature of the resulting mixture inside the reaction chamber is increased above the autoignition temperature; anda controller, comprising: a detection module that detects when a reaction temperature within the reaction chamber exceeds a flameout temperature of the mixture; anda correction module that outputs instructions, based on the detection module, to the heat extractor to increase a removal of heat from the reaction chamber to maintain an adiabatic temperature within the reaction chamber below the flameout temperature of the mixture and a maximum reaction temperature within the reaction chamber below the flameout temperature of the mixture. 15. The oxidizer of claim 14, wherein the reaction chamber further comprises a plurality of additional inlets. 16. The oxidizer of claim 14, wherein the reaction chamber further comprises a plurality of additional outlets. 17. The oxidizer of claim 14, wherein the means for maintaining a temperature comprises a heat exchanger that transfers heat from the reaction products to the mixture at or before the inlet. 18. The oxidizer of claim 14, wherein the means for maintaining a temperature is configured to mix diluents with fuel at or before the inlet. 19. The oxidizer of claim 14, wherein the oxidizer is configured to use heat from the reaction products to generate steam. 20. The oxidizer of claim 14, wherein the oxidizer is configured to use heat from the reaction products to drive a generator for power generation. 21. The oxidizer of claim 20, wherein the oxidizer is configured to drive a generator by a turbine or a piston engine that is configured to expand the reaction products from the reaction chamber. 22. The oxidizer of claim 14, wherein the oxidizer is configured to use heat from the reaction products to heat material that is not passed through the oxidizer. 23. The oxidizer of claim 14, wherein the oxidizer is configured to change a flow rate that the mixture is introduced into the reaction chamber through the inlet. 24. The oxidizer of claim 14, wherein the oxidizer is configured to change a flow rate that the reaction products are directed from the reaction chamber through the outlet. 25. The oxidizer of claim 14, further comprising a controller that is configured to change at least one of a flow of the mixture or a pressure of the mixture at or near the inlet.
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