Claims
- 1. A method of controlling a temperature profile within a preferential oxidation reactor to provide a temperature range within the reactor which favors the selective oxidation of CO in a hydrogen rich reformate stream by a preferential oxidation catalyst comprising the steps of:
flowing a stream of a mixture of a hydrogen rich reformate and oxygen over the preferential oxidation catalyst; flowing a stream of water proximate to the preferential oxidation catalyst so as the stream of water and the reformate stream passing over the catalyst are in a heat transfer arrangement; and maintaining the stream of water as a two phase stream from a point at which the water reaches its boiling temperature to a point proximate an outlet from which the stream of water exits the reactor.
- 2. The method of claim 1, wherein the step of maintaining the stream of water as a two phase stream comprises the step of controlling the flow rate of the water stream.
- 3. The method of claim 1, further comprising the step of controlling the pressure of the stream of water.
- 4. The method of claim 3, wherein the step of controlling the pressure comprises the step of creating pressures in the range of from about 1 atmosphere to about 10 atmospheres.
- 5. The method of claim 1, wherein the preferential oxidation catalyst is in a form selected from the group consisting of: a monolith, a foam, pellets, powder and a wash coat.
- 6. The method of claim 5, wherein the step of flowing a stream of water further comprises the step of flowing the stream through a heat exchanger wash coated in catalyst.
- 7. The method of claim 6, wherein the heat exchanger is a helical tube having contiguous fins or a plate and frame type heat exchanger.
- 8. The method of claim 1, wherein the temperature profile is in the range of from about 75° C. to about 300° C.
- 9. The method of claim 1, wherein the temperature profile is in the range of from about 100° C. to about 250° C.
- 10. A reactor for the selective oxidation of carbon monoxide in a hydrogen rich reformate stream comprising:
a reactor body; an inlet for the addition of a reformate stream to the reactor body; at least one oxygen inlet for the addition of oxygen to the reformate stream; a catalyst suitable for selective oxidation of carbon monoxide, located within the reactor body; a heat exchanger, having an inlet and an outlet, for removing heat from at least one of the catalyst and the reformate; a stream of water flowing through said heat exchanger; wherein said stream of water enters the heat exchanger at least partially as liquid water; and wherein said stream of water is a two phase mixture of water and steam throughout at least a portion of the reformate flow path.
- 11. The reactor of claim 10, wherein the catalyst is in a form selected from the group consisting of pellets, foam, a monolith, a powder, and a layer wash-coated onto a component of the heat exchanger.
- 12. The reactor of claim 10, wherein the heat exchanger comprises a cooling tube contiguous with the catalyst.
- 13. The reactor of claim 10, wherein the heat exchanger comprises a cooling jacket located proximate to an exterior wall of the reactor.
- 14. The reactor of claim 10 wherein the portion of the reformate flow path that is in heat exchange with one of liquid water and two phase water is substantially equal to the portion of the reformate flow path that contains catalyst.
- 15. The reactor of claim 10 further comprising:
a core in the reactor around which the stream of reformated is routed; and wherein the catalyst is arranged about the core.
- 16. The reactor of claim 15 wherein the core is hollow.
- 17. The reactor of claim 15, further comprising a unit for processing of a hydrocarbon fuel located within the core.
- 18. The reactor of claim 15, wherein the unit comprises a low temperature shift unit.
- 19. A reactor for the selective oxidation of carbon monoxide in a hydrogen rich reformate stream, the reactor comprising:
a reactor body; an inlet for the addition of a reformate stream to the reactor body; at least one inlet for the addition of oxygen to the reformate stream; and a substrate, wash coated with a catalyst suitable for selective oxidation of carbon monoxide contained within the reactor body wherein the substrate is a heat exchanger through which a coolant flows.
- 20. The reactor of claim 19, wherein the cooling medium comprises two phase water in liquid and gaseous phases.
- 21. The reactor of claim 19 wherein the substrate comprises a cooling tube having fins.
- 22. The reactor of claim 19, wherein the coolant flows in a generally countercurrent direction to the direction of flow of the reformate.
- 23. The reactor of claim 19, wherein the flow of the coolant is in a generally concurrent direction to the flow of the reformate.
- 24. The reactor of claim 19 further comprising a core contained within the reactor body around which the stream of reformate flows.
- 25. The reactor of claim 24 wherein the heat exchanger further comprises a helical tube having fins which is arranged about the core within the reactor body.
- 26. The reactor of claim 25, further comprising additional inlets through which oxygen is introduced to the reformate stream.
- 27. The reactor of claim 24 wherein the volume of the core is in the range of from about 10 percent to about 95 percent of the volume of the reactor.
- 28. A reactor for the selective oxidation of carbon monoxide in a hydrogen rich reformate stream comprising:
a reactor body having a reformate stream with a flow direction therein; a tube carrying the reformate stream having an inlet to the reactor body; a tube carrying an oxygen stream having an inlet to the tube carrying the reformate stream; a first helical tube carrying a two phase system of water and steam in a direction countercurrent to the flow direction of the reformate stream; a bed of steel shot through which the first helical tube travels and over which the reformate stream flows; a first bed of a selective oxidation catalyst located downstream of the bed of steel shot; a manifold into which the reformate stream flows; a oxygen inlet into the manifold; a second bed of a selective oxidation catalyst into which the reformate stream is flowed from the manifold; a second helical tube carrying water in a direction countercurrent to the direction of flow of the reformate upon exiting the manifold; a riser extending from the helical tube through the second bed of catalyst; a second bed of steel shot through which the second helical tube travels and over which the reformate stream flows; an outlet for the reformate stream; and wherein the riser is in fluid communication with the first helical tube outside of the reactor body.
- 29. A heat exchanger comprising:
two or more tubular sections each with an inlet and an outlet for permitting circulation of a heat exchange fluid through the tubular section; and,a connector between each tubular section for permitting a flow from the outlet of one tubular section to the inlet of the next tubular section.
- 30. The heat exchanger of claim 29 wherein the connectors are adapted and configured to be connected and unconnected nondestructively.
- 31. The heat exchanger of claim 30 where each connector has a seal to prevent leakage of heat exchange fluid, the seal being adapted to permit disassembly and reassembly of the tubular sections while still providing a seal against leakage.
- 32. The heat exchanger of claim 30 wherein the connectors comprise:
a manifold coupled to each tubular section, each manifold having a manifold inlet for fluid communication with an inlet of the tubular section, and a manifold outlet for fluid communication with the outlet of the same tubular section, each manifold having a section transfer inlet for fluid communication from another manifold, and a section transfer outlet for fluid communication to another manifold down stream in the fluid flow.
- 33. The heat exchanger of claim 32 where each manifold has a seal to prevent leakage of heat exchange fluid as it transfers from one manifold to another adapted to permit disassembly and reassembly of the tubular sections while still providing a seal against leakage.
- 34. The heat exchanger of claim 32 wherein the tubular sections are spaced and provide fluid flow within the tubular section along respective planes substantially parallel to each other, and the manifolds provide fluid flow in a direction angular to the planes of flow in the tubular sections.
- 35. The heat exchanger of claim 34 wherein the angular direction of flow through the manifolds is approximately 90 degrees with respect to the flow in the tubular sections.
- 36. The heat exchanger of claim 32 wherein each manifold is sized, configured, and attached to the adjacent manifolds so that the joined manifolds provide sufficient structural rigidity to transport or operate the heat exchanger with reduced support for the joined tubular sections.
- 37. The heat exchanger of claim 35 wherein each manifold is sized, configured, and attached to the adjacent manifolds so that the joined manifolds provide sufficient structural rigidity to transport or operate the heat exchanger with reduced support for the joined tubular sections.
- 38. The heat exchanger of claim 29 wherein each of the tubular sections have inner and outer surfaces and at least one of the sections has fins connected to and extending out of its outer surface.
- 39. The heat exchanger of claim 30 wherein each of the tubular sections have inner and outer surfaces and at least one of the sections has fins connected to and extending out of its outer surface.
- 40. The heat exchanger of claim 31 wherein each of the tubular sections have inner and outer surfaces and at least one of the sections has fins connected to and extending out of its outer surface.
- 41. The heat exchanger of claim 33 wherein each of the tubular sections have inner and outer surfaces and at least one of the sections has fins connected to and extending out of its outer surface.
- 42. The heat exchanger of claim 35 wherein each of the tubular sections have inner and outer surfaces and at least one of the sections has fins connected to and extending out of its outer surface.
- 43. The heat exchanger of claim 36 wherein each of the tubular sections have inner and outer surfaces and at least one of the sections has fins connected to and extending out of its outer surface.
- 44. The heat exchanger of claim 37 wherein each of the tubular sections have inner and outer surfaces and at least one of the sections has fins connected to and extending out of its outer surface.
- 45. The heat exchanger of claim 38 having fins on more than one tubular section and the fins on each tubular section having parameters including number of fins, spacing between fins, alignment of fins, material comprising the fins, coating on the fins, heat transfer coefficient, surface area, shape of individual fins, size of the individual fins, orientation with respect to the tubular section, and type of attachment to the tubular section and at least one of the tubular sections have fins which differ from the fins of at least one other tubular section by one or more of the parameters.
- 46. The heat exchanger of claim 39 having fins on more than one tubular section and the fins on each tubular section having parameters including number of fins, spacing between fins, alignment of fins, material comprising the fins, coating on the fins, heat transfer coefficient, surface area, shape of individual fins, size of the individual fins, orientation with respect to the tubular section, and type of attachment to the tubular section and at least one of the tubular sections have fins which differ from the fins of at least one other tubular section by one or more of the parameters.
- 47. The heat exchanger of claim 41 having fins on more than one tubular section and the fins on each tubular section having parameters including number of fins, spacing between fins, alignment of fins, material comprising the fins, coating on the fins, heat transfer coefficient, surface area, shape of individual fins, size of the individual fins, orientation with respect to the tubular section, and type of attachment to the tubular section and at least one of the tubular sections have fins which differ from the fins of at least one other tubular section by one or more of the parameters.
- 48. The heat exchanger of claim 33 having fins on more than one tubular section and the fins on each tubular section having parameters including number of fins, spacing between fins, alignment of fins, material comprising the fins, coating on the fins, heat transfer coefficient, surface area, shape of individual fins, size of the individual fins, orientation with respect to the tubular section, and type of attachment to the tubular section and at least one of the tubular sections have fins which differ from the fins of at least one other tubular section by one or more of the parameters.
- 49. The heat exchanger of claim 29 wherein at least one of the tubular sections have inner and outer surfaces and at least one of the inner or outer surfaces is coated with a catalyst for promoting a reaction within the heat transfer fluid.
- 50. The heat exchanger of claim 46 wherein the fins are die cast onto the outer surface of the tubular section.
- 51. The heat exchanger of claim 38 wherein the fins are die cast onto the outer surface of the tubular section.
- 52. The heat exchanger of claim 41 wherein the fins are die cast onto the outer surface of the tubular section.
- 53. The heat exchanger of claim 41 wherein the tubular section is stainless steel and the fins are aluminum.
- 54. The heat exchanger of claim 50 wherein the fins on one of the tubular sections is misaligned with respect to the fins on another tubular section in a manner sufficient to increase turbulence in the flow of a fluid passing over the fins of both tubular sections.
- 55. The heat exchanger of claim 29 wherein each tubular section has a flow path of from its inlet to its outlet of a defined flow path length, and at least two of the tubular sections have differing flow path lengths.
- 56. The heat exchanger of claim 30 wherein each tubular section has a flow path of from its inlet to its outlet of a defined flow path length, and at least two of the tubular sections have differing flow path lengths.
- 57. The heat exchanger of claim 40 wherein each tubular section has a flow path of from its inlet to its outlet of a defined flow path length, and at least two of the tubular sections have differing flow path lengths.
- 58. The heat exchanger of claim 41 wherein each tubular section has a flow path of from its inlet to its outlet of a defined flow path length, and at least two of the tubular sections have differing flow path lengths.
- 59. The heat exchanger of claim 38 including a catalyst optionally on the fins, or on the inner surface of the tubular section, or both, for promoting a desired reaction in a heat exchange fluid intended to flow over the fins or through the tubular section.
- 60. The heat exchanger of claim 39 including a catalyst optionally on the fins, or on the inner surface of the tubular section, or both, for promoting a desired reaction in a heat exchange fluid intended to flow over the fins or through the tubular section.
- 61. The heat exchanger of claim 40 including a catalyst optionally on the fins, or on the inner surface of the tubular section, or both, for promoting a desired reaction in a heat exchange fluid intended to flow over the fins or through the tubular section.
- 62. The heat exchanger of claim 41 including a catalyst optionally on the fins, or on the inner surface of the tubular section, or both, for promoting a desired reaction in a heat exchange fluid intended to flow over the fins or through the tubular section.
- 63. The heat exchanger of claim 42 including a catalyst optionally on the fins, or on the inner surface of the tubular section, or both, for promoting a desired reaction in a heat exchange fluid intended to flow over the fins or through the tubular section.
- 64. The heat exchanger of claim 43 including a catalyst optionally on the fins, or on the inner surface of the tubular section, or both, for promoting a desired reaction in a heat exchange fluid intended to flow over the fins or through the tubular section.
- 65. The heat exchanger of claim 38 including that the fins are made at least in part of a catalyst which will promote a desired reaction in a heat exchange fluid intended to flow over the fins.
- 66. A method of making a heat exchanger comprising the steps of:
a. forming a tubular conduit of a first metal into a tubular section; b. placing the tubular section in a die; and, c. casting a second metal onto an outer surface of the tubular section in the form of fins (fins can be any extending protrusion of any size, shape, orientation with respect to each other or the tubular section).
- 67. The method of claim 66 including the step of coating the fins with a catalyst for promoting a desired reaction in a heat transfer fluid intended to contact the fins during heat transfer operations.
- 68. The method of claim 66 including the steps of connecting the tubular section to a connector and connecting at least two tubular sections together with the connector.
- 69. The method of claim 68 including the steps of optionally coating the fins or an inner surface of the tubular section or both with a catalyst for promoting a desired reaction in a heat transfer fluid intended to contact the fins during heat transfer operations.
- 70. The method of claim 66 wherein the first metal is different than the second metal.
- 71. The method of claim 70 wherein the first metal is stainless steel and the second metal is an aluminum-based metal.
RELATED APPLICATIONS
[0001] The present invention claims priority of U.S. Provisional Patent Application 60/388,555 filed Jun. 13, 2002 and U.S. Patent Application 09/562,787 filed May 2, 2000 which claims priority of U.S. Provisional Patent Applications 60/132,184 and 60,132,259, both filed May 3, 1999.
Provisional Applications (1)
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Number |
Date |
Country |
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60388555 |
Jun 2002 |
US |