A premix burner arrangement for safely oxygen-enriching a premix air-fuel combustion system is disclosed. In the disclosed burner arrangement, a first conduit is arranged and disposed to provide a first gas stream. The first gas stream is a self-reactive or self-flammable premixture comprising air a
A premix burner arrangement for safely oxygen-enriching a premix air-fuel combustion system is disclosed. In the disclosed burner arrangement, a first conduit is arranged and disposed to provide a first gas stream. The first gas stream is a self-reactive or self-flammable premixture comprising air and a combustible gas. At least one second conduit is arranged and disposed to provide a second gas stream circumferentially around the first gas stream. The second gas stream includes oxygen. The premix burner arrangement is configured to combust or react the first stream at a temperature at least 1000° F. greater than the temperature of the second stream. A method and combustion system including the premix burner arrangement are also disclosed.
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1. A premix burner arrangement comprising: a first conduit arranged and disposed to provide a first gas stream, the first gas stream being a self-reactive or self-flammable premixture comprising air and a combustible gas; andat least one second conduit arranged and disposed to provide a second gas s
1. A premix burner arrangement comprising: a first conduit arranged and disposed to provide a first gas stream, the first gas stream being a self-reactive or self-flammable premixture comprising air and a combustible gas; andat least one second conduit arranged and disposed to provide a second gas stream circumferentially around the first gas stream, the second gas stream including oxygen;wherein the premix burner arrangement is configured to combust or react the first stream at a temperature at least 1000° F. greater than the temperature of the second stream, the premix burner arrangement further being configured to provide a velocity ratio of the second gas stream to the first gas stream sufficiently low to inhibit mixing of the first gas stream with the second gas stream. 2. The burner arrangement of claim 1, wherein the at least one second conduit comprises a concentric conduit that surrounds the first conduit. 3. The burner arrangement of claim 1, wherein the at least one second conduit includes a series of multiple nozzles or orifices that are arranged around the first conduit. 4. The burner arrangement of claim 1, wherein the velocity ratio of the second gas stream to the first gas stream is less than about 1.0. 5. The burner arrangement of claim 1, wherein the velocity ratio of the second gas stream to the first gas stream is less than about 0.5. 6. The burner arrangement of claim 1, wherein the velocity ratio of the second gas stream to the first gas stream is from about 0.1 to about 0.5. 7. The burner arrangement of claim 1, wherein the combustible gas is selected from the group consisting of gaseous hydrocarbon, CO, hydrogen-containing gas, and combinations thereof. 8. The burner arrangement of claim 1, wherein the second gas stream includes oxygen in a concentration greater than about 50 vol %. 9. A combustion method comprising: providing a first gas stream, the first gas stream being a self-reactive or self-flammable pre-mixture comprising air and a combustible gas in a first conduit; andproviding a second gas stream circumferentially around the first gas stream with at least one second conduit, the second gas stream including oxygen;wherein the first stream is reacting or combusting and is at a temperature at least 1000° F. higher than the second stream and the first gas stream and second gas stream are provided with a velocity ratio of the second gas stream to the first gas stream sufficiently low to inhibit mixing of the first gas stream with the second gas stream. 10. The method of claim 9, wherein the velocity ratio of the second gas stream to the first gas stream is less than about 1.0. 11. The method of claim 9, wherein the velocity ratio of the second gas stream to the first gas stream is less than about 0.5. 12. The method of claim 9, wherein the velocity ratio of the second gas stream to the first gas stream is from about 0.1 to about 0.5. 13. The method of claim 9, the combustible gas is selected from the group consisting of gaseous hydrocarbon, CO, hydrogen-containing gas, and combinations thereof. 14. The method of claim 9, wherein the second gas stream includes oxygen in a concentration greater than about 50 vol %. 15. A combustion system comprising: a premix burner arrangement having a first conduit and at least one second conduit, the first conduit being arranged and disposed to provide a first gas stream, the first gas stream being a self-reactive or self-flammable pre-mixture comprising air and a combustible gas and the at least one second conduit being arranged and disposed to provide a second gas stream including oxygen circumferentially around the first gas stream; anda burner block forming a precombustion zone configured to receive the first gas stream and the second gas stream;wherein the premix burner arrangement is configured to combust or react the first stream at a temperature at least 1000° F. greater than the temperature of the second stream, the premix burner arrangement further being configured to provide a velocity ratio of the second gas stream to the first gas stream sufficiently low to inhibit mixing of the first gas stream with the second gas stream. 16. The system of claim 15, wherein the velocity ratio of the second gas stream to the first gas stream is less than about 1.0. 17. The system of claim 15, wherein the velocity ratio of the second gas stream to the first gas stream is less than about 0.5. 18. The system of claim 15, wherein the velocity ratio of the second gas stream to the first gas stream is from about 0.1 to about 0.5. 19. The system of claim 15, wherein the combustible gas is selected from the group consisting of gaseous hydrocarbon, CO, hydrogen-containing gas, and combinations thereof. 20. The system of claim 15, wherein the second gas stream includes oxygen in a concentration greater than about 50 vol %.
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이 특허에 인용된 특허 (9)
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