초록 ▼

A single-pipe cylinder-type reformer includes a plurality of circular cylinders standing upright coaxially and forming therebetween a zigzag gas flow path allowing a raw material gas to flow therein, a radiation cylinder coaxially arranged inside the plurality of circular cylinders, a burner arrange

A single-pipe cylinder-type reformer includes a plurality of circular cylinders standing upright coaxially and forming therebetween a zigzag gas flow path allowing a raw material gas to flow therein, a radiation cylinder coaxially arranged inside the plurality of circular cylinders, a burner arranged at one end of a center of the radiation cylinder for generating a combustion gas, a reforming catalyst layer obtained by packing with a reforming catalyst at least a first gas flow path section of the gas flow path closest to the burner. A metal pre-heat layer formed on an upstream side of the reforming catalyst layer is packed with a metal packing. Helical dividing means are provided in each gas flow path section of the gas flow path to extend in the axial direction of the circular cylinders. The helical dividing means helically divide a gas and make it flow through the first gas flow section.

대표청구항 ▼

What is claimed is: 1. A single pipe cylinder type reformer including a plurality of circular cylinders standing upright coaxially and forming therebetween a gas flow path allowing a raw material gas to flow therein and having a plurality of gas flow path sections, each being disposed between every

What is claimed is: 1. A single pipe cylinder type reformer including a plurality of circular cylinders standing upright coaxially and forming therebetween a gas flow path allowing a raw material gas to flow therein and having a plurality of gas flow path sections, each being disposed between every pair of adjacent circular cylinders and having an annular cross-section, a radiation cylinder coaxially arranged inside the plurality of circular cylinders and forming at an outer periphery thereof an exhaust flow path, a burner arranged at one end of a center of the radiation cylinder for generating a combustion gas allowed to flow within the exhaust flow path in the reverse direction to the flowing direction of the raw material gas in a first gas flow path section, a reforming catalyst layer obtained by packing with a reforming catalyst into at least the first gas flow path section closest to the burner among the plurality of gas flow path sections, in which the raw material gas is reformed by making use of only steam, comprising: a metal pre-heat layer packed with a metal packing at an upstream end of the reforming catalyst layer; a second gas flow path section with an annular cross-section, the second gas flow path section being formed around the reforming catalyst layer packed with the reforming catalyst, communicating with the reforming catalyst layer with one end-side inlet port thereof, and allowing a gas to flow in a direction opposite to that of a gas flow in the first gas flow path section; a third gas flow path section with an annular cross-section, the third gas flow path section being formed around the second gas flow path section, communicating at one end-side inlet port thereof with the other end-side outlet port of the second gas flow path section allowing a gas to flow in a direction opposite to that of a gas flow in the second gas flow path section, and being provided with a CO modifying catalyst layer therein; a fourth gas flow path section with an annular cross-section, the fourth gas flow path section being formed around the third gas flow path section, communicating with the other end-side outlet port of the third gas flow path section with one end-side inlet port thereof, allowing a gas to flow in a direction opposite to that of a gas flow in the third gas flow path section, and being provided with a CO selective oxidation catalyst layer therein; a heating channel which serves as a raw material gas flow path formed between the third and fourth gas flow path sections, has an inlet port at one end side thereof, and allows a raw material gas in the fourth gas flow path section to flow in a direction opposite to that of a gas flow in the fourth gas flow path section and to reverse near one end of the fourth gas flow path section, and allows the raw material gas in the third gas flow path section to flow in the same direction as that of a gas flow in the fourth gas flow path section; an annular mixing chamber to be connected to an air supply pipe on an upstream side of the fourth gas flow path section; a discharge port for guiding the gas that flows into the fourth gas flow path section to the mixing chamber; an annular inflow chamber into which a reformed gas mixed with air flows through one inlet port so as to be guided to a starting terminal of the CO selective oxidation catalyst layer; and an inflow port for allowing the inflow chamber and the starting terminal of the CO selective oxidation catalyst layer to communicate with each other, wherein axial lengths of the third and fourth gas flow path sections are shorter than those of the first and second gas flow path sections, and another CO modifying catalyst layer is formed on an upstream side of the fourth gas flow path section. 2. A reformer according to claim 1, wherein helical dividing means extending in an axial direction of the circular cylinders is provided in the first gas flow path section so that a gas helically flows through the pre-heat layer and the reforming catalyst layer. 3. A reformer according to claim 2, wherein the dividing means formed in the first gas flow path section is comprised of a plurality of helical fins or a plurality of helical round rods that divide the first gas flow path section into sectors in a cross-section thereof. 4. A reformer according to claim 1, further comprising dividing means formed in the second gas flow path section is comprised of a plurality of helical round rods that divide the second gas flow path section into sectors in a cross-section thereof. 5. A reformer according to claim 1, wherein a plurality of helical fins fixed to an inner circular cylinder that forms the third gas flow path section are provided in the third gas flow path section so as to divide the third gas flow path section into sectors in a cross-section thereof. 6. A reformer according to claim 1, wherein an outer circumferential wall of the CO selective oxidation catalyst layer is formed inside an outer circumferential wall of the fourth gas flow path section, and a space formed between the outer circumferential wall of the fourth gas flow path section and the outer circumferential wall of the CO selective oxidation catalyst layer and divided from the mixing chamber serves as a cooling flow path where a cooling fluid flows. 7. A reformer according to claim 6, wherein a dividing member is provided in the cooling flow path to divide the cooling flow path helically. 8. A reformer according to claim 6, wherein the cooling fluid to be supplied into the cooling flow path is supplied to flow in a direction opposite to a flowing direction of a gas to be supplied into the CO selective oxidation catalyst layer. 9. A reformer according to claim 6, wherein combustion air to be combusted by the burner is used as the cooling fluid. 10. A reformer according to claim 5, wherein an OFF gas discharged from a fuel pole of a fuel cell is used as the cooling fluid. 11. A single-pipe cylinder type reformer including a plurality of circular cylinders standing upright coaxially and forming therebetween a gas flow path allowing a raw material gas to flow therein and having a plurality of gas flow path sections, each being disposed between every pair of adjacent circular cylinders and having an annular cross-section, a radiation cylinder coaxially arranged inside the plurality of circular cylinders and forming at an outer periphery thereof an exhaust flow path, a burner arranged at one end of a center of the radiation cylinder for generating a combustion gas allowed to flow within the exhaust flow path in the reverse direction to the flowing direction of the raw material gas in a first gas flow section, a reforming catalyst layer obtained by packing with a reforming catalyst into at least the first gas flow path section closest to the burner among the plurality of gas flow path sections, in which the raw material gas is reformed by making use of only steam, comprising: helical dividing means extending in the first gas flow path section in an axial direction of the circular cylinders, the helical dividing means being provided within the first gas flow path section including the reforming catalyst layer for helically dividing a gas and making it flow helically through the first gas flow path section; a second gas flow path section with an annular cross-section, the second gas flow path section being formed around the reforming catalyst layer packed with the reforming catalyst, communicating with the reforming catalyst layer with one end-side inlet port thereof, and allowing a gas to flow in a direction opposite to that of a gas flow in the first gas flow path section; a third gas flow path section with, an annular cross-section, the third gas flow path section being formed around the second gas flow path section, communicating at one end-side inlet port thereof with the other end-side outlet port of the second gas flow path section, allowing a gas to flow in a direction opposite to that of a gas flow in the second gas flow path section, and being provided with a CO modifying catalyst layer therein; a fourth gas flow path section with an annular cross-section, the fourth gas flow path section being formed around the third gas flow path section, communicating with the other end-side outlet port of the third gas flow path section with one end-side inlet port thereof, allowing a gas to flow in a direction opposite to that of a gas flow in the third gas flow path section, and being provided with a CO selective oxidation catalyst layer therein; a heating channel which serves as a raw material gas flow path formed between the third and fourth gas flow path sections, has an inlet port at one end side thereof, and allows a raw material gas in the fourth gas flow path section to flow in a direction opposite to that of a gas flow in the fourth gas flow path section and to reverse near one end of the fourth gas flow path section, and allows the raw material gas in the third gas flow path section to flow in the same direction as that of a gas flow in the fourth gas flow path section; an annular mixing chamber to be connected to an air supply pipe on an upstream side of the fourth gas flow path section; a discharge port for guiding the gas that flows into the fourth gas flow path section to the mixing chamber; an annular inflow chamber into which a reformed gas mixed with air flows through one inlet port so as to be guided to a starting terminal of the CO selective oxidation catalyst layer; and an inflow port for allowing the inflow chamber and the starting terminal of the CO selective oxidation catalyst layer to communicate with each other, wherein axial lengths of the third and fourth gas flow path sections are shorter than those of the first and second gas flow path sections, and another CO modifying catalyst layer is formed on an upstream side of the fourth gas flow path section. 12. A reformer according to claim 11, wherein the dividing means formed in the first gas flow path section is comprised of a plurality of helical fins or a plurality of helical round rods that divide the first gas flow path section into sectors in a cross-section thereof. 13. A reformer according to claim 11, comprising a pre-heat layer packed with a metal packing at an upstream end of the reforming catalyst layer. 14. A reformer according to claim 11, wherein the dividing means formed in the second gas flow path section is comprised of a plurality of helical round rods that divide the second gas flow path section into sectors in a cross-section thereof. 15. A reformer according to claim 11, wherein a plurality of helical fins fixed to an inner circular cylinder that forms the third gas flow path section are provided in the third gas flow path section so as to divide the third gas flow path section into sectors in a cross-section thereof. 16. A reformer according to claim 11, wherein an outer circumferential wall of the CO selective oxidation catalyst layer is formed inside an outer circumferential wall of the fourth gas flow path section, and a space formed between the outer circumferential wall of the fourth gas flow path section and the outer circumferential wall of the CO selective oxidation catalyst layer and divided from the mixing chamber serves as a cooling flow path where a cooling fluid flows. 17. A reformer according to claim 16, wherein a dividing member is provided in the cooling flow path to divide the cooling flow path helically. 18. A reformer according to claim 16, wherein the cooling fluid to be supplied into the cooling flow path is supplied to flow in a direction opposite to a flowing direction of a gas to be supplied into the CO selective oxidation catalyst layer. 19. A reformer according to claim 16, wherein combustion air to be combusted by the burner is used as the cooling fluid. 20. A reformer according to claim 11, wherein an OFF gas discharged from a fuel pole of a fuel cell is used as the cooling fluid.