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A preferential oxidation reactor is provided including a plurality of reactor sections. The reactor sections are individually optimized for operating at a preferred reaction temperature. In one embodiment, each reactor subsection includes a respective coolant flow for manipulating the operating temp

A preferential oxidation reactor is provided including a plurality of reactor sections. The reactor sections are individually optimized for operating at a preferred reaction temperature. In one embodiment, each reactor subsection includes a respective coolant flow for manipulating the operating temperature of the respective subsection. In another embodiment, a first section includes a lower temperature catalyst substrate, a second reactor section includes a higher temperature (i.e. normal) catalyst substrate and a third reactor section includes a lower temperature catalyst substrate. Yet another embodiment includes modifying the catalyst substrates of the respective subsections through the inclusion of promoters. Still another embodiment includes varying a density of the catalyst substrate across the reactor sections. Each of the embodiments enable quick light-off of the reactor, while limiting a reverse water-gas shift reaction.

대표청구항 ▼

1. A preferential oxidation reactor for reducing a carbon monoxide content of a gas stream which contains hydrogen, the reactor comprising:at least first and second reactor sections;said first reactor section having a first gas passage through which the gas stream flows, and having a surface support

1. A preferential oxidation reactor for reducing a carbon monoxide content of a gas stream which contains hydrogen, the reactor comprising:at least first and second reactor sections;said first reactor section having a first gas passage through which the gas stream flows, and having a surface supporting a first catalyst comprising a first metal for promoting oxidation of carbon monoxide in the gas stream;said second reactor section having a second gas passage in flow communication with said first gas passage and having a surface supporting a second catalyst comprising a second metal different from the said metal; andcontrol means for maintaining a first temperature within said first gas passage at a value different than a second temperature within said second gas passage; wherein said first catalyst is characterized by promoting oxidation of the carbon monoxide at a different rate at said first temperature, as compared to a rate at which said second catalyst is operable at said first temperature to oxidize the carbon monoxide. 2. The preferential oxidation reactor of claim 1, wherein said first catalyst comprises a support different than said second catalyst support. 3. The preferential oxidation reactor of claim 1, further comprising a third reactor section having a third gas passage through which the gas stream flows, and having a surface supporting a third catalyst comprising a third metal. 4. The preferential oxidation reactor of claim 3, wherein said third catalyst has a composition different from at least one of said first and second catalysts. 5. The preferential oxidation reactor of claim 3, wherein a density of said third catalyst differs from a density of at least one of said first and second catalysts. 6. The preferential oxidation reactor of claim 3, wherein said third metal is selected from a group consisting of ruthenium (Ru), gold (Au). 7. The preferential oxidation reactor of claim 1, wherein a density of said first catalyst differs from a density of said second catalyst. 8. The preferential oxidation reactor of claim 1, wherein each of said first and second gas passages include at least one convoluted element for supporting said respective catalysts. 9. The preferential oxidation reactor of claim 8, wherein said at least one convoluted element is selected from a group consisting of foam, fins and corrugated sheet. 10. The preferential oxidation reactor of claim 1, wherein said control means comprises first and second coolant passages respectively associated with said first and second reactor sections and in respective heat transfer relationship with said first and second gas passages. 11. The preferential oxidation reactor of claim 10, wherein said control means varies respective coolant flows through said first and second coolant passages and a temperature of said coolant flows, thereby controlling said first and second temperatures of said first and second gas passages. 12. The preferential oxidation reactor of claim 1, wherein said first metal is selected from a group consisting of ruthenium (Ru), gold (Au) and mixtures thereof. 13. The preferential oxidation reactor of claim 1, wherein said second metal is selected from a group consisting of iridium (Ir), platinum (Pt), palladium (Pd) and mixtures thereof. 14. The preferential oxidation reactor of claim 1, wherein respective densities of said first and second catalysts decrease in a flow path direction of the gas stream. 15. The preferential oxidation reactor of claim 1 wherein said first catalyst is characterized by promoting oxidation of the carbon monoxide at a greater rate at said first temperature, as compared to a rate at which said second catalyst is operable at said first temperature to oxidize the carbon monoxide. 16. A fuel cell system comprising a preferential oxidation reactor according to claim 1, wherein said preferential oxidation reactor comprises a single reactor chamber having said at least first and second reactor sections. 17. A prefere ntial oxidation reactor for reducing a carbon monoxide content of a gas stream which contains hydrogen, the reactor comprising:at least first, second and third reactor sections;said first reactor section having a first gas passage through which the gas stream flows, and having a surface supporting a first catalyst for promoting oxidation of carbon monoxide in the gas stream;said second reactor section having a second gas passage in flow communication with said first gas passage and having a surface supporting a second catalyst; andsaid third reactor section having a third gas passage through which the gas stream flows, and having a surface supporting a third catalyst; andcontrol means for maintaining a first temperature within said first gas passage at a value different than a second temperature within said second gas passage,wherein said first catalyst is characterized by promoting oxidation of the carbon monoxide at a different rate at said first temperature, as compared to a rate at which said second catalyst is operable at said first temperature to oxidize the carbon monoxide; andwherein respective densities of said first, second and third catalysts decrease in a flow path direction of the gas stream. 18. A preferential oxidation reactor for reducing a carbon monoxide content of a gas stream which contains hydrogen, the reactor comprising:at least first and second reactor sections;said first reactor section having a first gas passage through which the gas stream flows, and having a surface supporting a first catalyst for promoting oxidation of carbon monoxide in the gas stream;said second reactor section having a second gas passage in flow communication with said first gas passage and having a surface supporting a second catalyst; andcontrol means for maintaining a first temperature within said first gas passage at a value different than a second temperature within said second gas passage,wherein said first catalyst is characterized by promoting oxidation of the carbon monoxide at a different rate at said first temperature, as compared to a rate at which said second catalyst is operable at said first temperature to oxidize the carbon monoxide; andwherein at least one of said first and second catalysts further comprises a promoter for promoting the oxidation of the carbon monoxide at a temperature different than the temperature at which such oxidation would occur without said promoter. 19. The preferential oxidation reactor of claim 18, wherein said promoter is tin oxide (SnO 2 ). 20. A preferential oxidation reactor for reducing a carbon monoxide content of a gas stream which contains hydrogen, the reactor comprising:at least first, second and third reactor sections;said first reactor section having a first gas passage through which the gas stream flows, and having a surface supporting a first catalyst for promoting oxidation of carbon monoxide in the gas stream;said second reactor section having a second gas passage in flow communication with said first gas passage and having a surface supporting a second catalyst;said third reactor section having a third gas passage through which the gas stream flows, and having a surface supporting a third catalyst; andcontrol means for maintaining a first temperature within said first gas passage at a value different than a second temperature within said second gas passage,wherein said first catalyst is characterized by promoting oxidation of the carbon monoxide at a different rate at said first temperature, as compared to a rate at which said second catalyst is operatable at said first temperature to oxidize the carbon monoxide; andwherein at least one of said first, second and third catalysts further comprises a promoter for promoting the oxidation of the carbon monoxide at a temperature different than the temperature at which such oxidation would occur without said promoter. 21. The preferential oxidation reactor of claim 20, wherein said promoter is tin oxide (SnO 2 ). 22. A meth od for treating a hydrogen-containing reformate stream within a preferential oxidation reactor to reduce the carbon monoxide content of the reformate stream, said method comprising the steps of:reacting a first portion of carbon monoxide in the reformate stream at a first temperature in the presence of a first catalyst comprising a first metal within a first section of the reactor to oxidize said first portion of carbon monoxide;directing the reformate stream from said first reactor section to a second reactor section;reacting a second portion of carbon monoxide in the reformate stream in said second reactor section in the presence of a second catalyst comprising a second metal different from the said first metal at a second temperature to oxidize a second portion of the carbon monoxide; andmaintaining said second temperature lower than said first temperature. 23. The method of claim 22 further comprising the steps of:directing the reformate stream from said second reactor section to a third reactor section;reacting a third portion of carbon monoxide in the reformate stream in said third reactor section in the presence of a third catalyst at a third temperature; andmaintaining said third temperature at a value different from at least one of said first and second temperatures. 24. The method of claim 23 wherein said third temperature is lower than at least one of said first and second temperatures, said third catalyst and said third temperature are selected to oxidize carbon monoxide while minimizing a reverse water gas shift reaction. 25. The method of claim 22 wherein said first catalyst and said first temperature are selected to promote oxidation of carbon monoxide thereby providing light-off of said oxidation reaction at said first temperature. 26. A method for treating a hydrogen-containing reformate stream within a preferential oxidation reactor to reduce the carbon monoxide content of the reformate stream, said method comprising the steps of:reacting a first portion of carbon monoxide in the reformate stream at a first temperature in the presence of a first catalyst within a first section of the reactor to oxidize said first portion of carbon monoxide;directing the reformate stream from said first reactor section to a second reactor section;reacting a second portion of carbon monoxide in the reformate stream in said second reactor section in the presence of a second catalyst at a second temperature to oxidize a second portion of the carbon monoxide; andmaintaining said second temperature lower than said first temperature,wherein said second catalyst and said second temperature are selected to promote oxidation of carbon monoxide while minimizing a reverse water gas shift reaction. 27. A method for treating a hydrogen-containing reformate stream within a preferential oxidation reactor to reduce the carbon monoxide content of the reformate stream, said method comprising the steps of:reacting a first portion of carbon monoxide in the reformate stream at a first temperature in the presence of a first catalyst within a first section of the reactor to oxidize said first portion of carbon monoxide;directing the reformate stream from said first reactor section to a second reactor section;reacting a second portion of carbon monoxide in the reformate stream in said second reactor section in the presence of a second catalyst at a second temperature to oxidize a second portion of the carbon monoxide; andmaintaining said second temperature greater than said first temperature. 28. The method of claim 27 further comprising the steps of:directing the reformate stream from said second reactor section to a third reactor section;reacting a third portion of carbon monoxide in the reformate stream in said third reactor section in the presence of a third catalyst at a third temperature; andmaintaining said third temperature at a value different from at least one of said first and second temperatures. 29. The method of claim 28 wherein said th ird temperature is lower than at least one of said first and second temperatures, said third catalyst and said third temperature are selected to oxidize carbon monoxide while minimizing a reverse water gas shift reaction. 30. The method of claim 27 wherein said first catalyst and said first temperature are selected to promote oxidation of the carbon monoxide at a greater rate at said first temperature, as compared to a rate at which said second catalyst is operable at said first temperature to oxidize the carbon monoxide, thereby providing light-off of said oxidation reaction at said first temperature. 31. The method of claim 27 wherein said second catalyst and said second temperature are selected to promote preferential oxidation of carbon monoxide in the presence of hydrogen.