A reforming device includes a reforming part that subjects a hydrocarbon-based raw material to be reformed to a reforming reaction to form a reducing agent to be supplied to a reducing catalyst for reducing nitrogen oxide selectively. The reforming part has a reforming reaction region through which
A reforming device includes a reforming part that subjects a hydrocarbon-based raw material to be reformed to a reforming reaction to form a reducing agent to be supplied to a reducing catalyst for reducing nitrogen oxide selectively. The reforming part has a reforming reaction region through which the raw material to be reformed passes and is reacted with supplied hydrogen atoms supplied so as to be reformed to the reducing agent. For example, a hydrogen permeable membrane having a first surface and a second surface may be provided in the reforming part to permeate hydrogen atoms from the first surface to the second surface and to produce the hydrogen atoms on the second surface. The reforming device can be suitably used for an exhaust gas control system for cleaning exhaust gas, for example.
대표청구항▼
What is claimed is: 1. A reducing agent forming device comprising: a reforming part that subjects a hydrocarbon-based raw material to be reformed to a reforming reaction to form a reducing agent to be supplied to a reducing catalyst part for reducing nitrogen oxide selectively; an inlet for flowing
What is claimed is: 1. A reducing agent forming device comprising: a reforming part that subjects a hydrocarbon-based raw material to be reformed to a reforming reaction to form a reducing agent to be supplied to a reducing catalyst part for reducing nitrogen oxide selectively; an inlet for flowing raw material into said reforming part; an outlet for flowing the reducing agent to the reducing catalyst part; and a hydrogen permeable membrane for supplying hydrogen atoms to the reforming part, the hydrogen permeable membrane having a first surface and a second surface; and a hydrogen supply means for supplying hydrogen molecules to the first surface of the hydrogen permeable membrane, the hydrogen supply means having an electrolytic film through which electric current passes and water supply means for supplying water to a first surface of the electrolytic film, wherein the reforming part has a reforming reaction region through which the raw material to be reformed passes and is reacted with the hydrogen atoms supplied by the hydrogen permeable membrane so as to be reformed to the reducing agent, the hydrogen permeable membrane dissociates the hydrogen molecules supplied to the first surface from the hydrogen supply means into hydrogen atoms and makes the hydrogen atoms permeate from the first surface to the second surface to produce the hydrogen atoms on the second surface, the electrolytic film has said first surface and a second surface opposite thereto, the second surface of the electrolytic film faces the first surface of the hydrogen permeable membrane, and when electric current is passed through the electrolytic film, the water supplied from the water supply means is decomposed on the first surface of the electrolytic film through electrolysis to produce hydrogen molecules on the second surface of the electrolytic film and the hydrogen molecules are supplied to the first surface of the hydrogen permeable membrane. 2. The reducing agent forming device as in claim 1, wherein the reforming reaction region is within a range of sub-micron from the second surface of the hydrogen permeable membrane. 3. The reducing agent forming device as in claim 1, further comprising a raw material supply unit for supplying the raw material to be reformed to the first surface of the hydrogen permeable membrane, wherein the first surface of the hydrogen permeable membrane is provided with a hydrogen forming catalyst for forming hydrogen from the raw material to be reformed and a catalyst carrier for carrying the hydrogen forming catalyst. 4. The reducing agent forming device as in claim 3, further comprising a promoter for promoting hydrogen formation by the hydrogen forming catalyst, wherein the promoter is provided on the first surface of the hydrogen permeable membrane. 5. The reducing agent forming device as in claim 3, wherein the hydrogen forming catalyst is diffused and carried in fine particles on the catalyst carrier. 6. The reducing agent forming device as in claim 5, wherein the catalyst carrier is made of a metal oxide formed by chemically combining constituent metal of the hydrogen permeable membrane with oxygen. 7. The reducing agent forming device as in claim 6, wherein the hydrogen permeable membrane is formed integrally with the catalyst carrier. 8. The reducing agent forming device as in claim 1, further comprising an oxygen supply means for supplying oxygen into the reforming part. 9. The reducing agent forming device as in claim 1, further comprising an oxygen supply means for supplying the reforming part with oxygen, wherein the oxygen supply means is constructed so as to supply oxygen formed through the electrolysis to the reforming part. 10. A reducing agent forming device comprising: a reforming part that subjects a hydrocarbon-based raw material to be reformed to a reforming reaction to form a reducing agent to be supplied to a reducing catalyst part for reducing nitrogen oxide selectively; an inlet for flowing raw material into said reforming part; an outlet for flowing the reducing agent to the reducing catalyst part; an oxygen supply means for supplying oxygen to the reforming part; and a hydrogen permeable membrane for supplying hydrogen atoms to the reforming part, the hydrogen permeable membrane having a first surface and a second surface; and a hydrogen supply means for supplying hydrogen molecules to the first surface of the hydrogen permeable membrane, the hydrogen supply means having an electrolytic film through which electric current passes and water supply means for supplying water to a first surface of the electrolytic film, wherein the reforming part has a reforming reaction region through which the raw material to be reformed passes and is reacted with the hydrogen atoms and the oxygen so as to be reformed to the reducing agent, the hydrogen permeable membrane dissociates the hydrogen molecules supplied to the first surface from the hydrogen supply means into hydrogen atoms and makes the hydrogen atoms permeate from the first surface to the second surface to produce the hydrogen atoms on the second surface, the electrolytic film has said first surface and a second surface opposite thereto, the second surface of the electrolytic film faces the first surface of the hydrogen permeable membrane, and when electric current is passed through the electrolytic film, the water supplied from the water supply means is decomposed on the first surface of the electrolytic film through electrolysis to produce hydrogen molecules on the second surface of the electrolytic film and the hydrogen molecules are supplied to the first surface of the hydrogen permeable membrane. 11. An exhaust gas control system for an internal combustion engine, the system comprising: an exhaust gas passage through which exhaust gas exhausted from the engine flows; a reducing catalyst part, located in the exhaust gas passage, for selectively reducing nitrogen oxide in the exhaust gas; a reforming part that subjects fuel used for the engine to a reforming reaction to form a reducing agent to be supplied to the reducing catalyst; an inlet passage for flowing fuel into the reforming part; an outlet passage for flowing reducing agent to the reducing catalyst part in the exhaust gas passage, a hydrogen permeable membrane for supplying hydrogen atoms to the reforming part, the hydrogen permeable membrane having a first surface and a second surface; and a hydrogen supply means for supplying hydrogen molecules to the first surface of the hydrogen permeable membrane, the hydrogen supply means having an electrolytic film through which electric current passes and water supply means for supplying water to a first surface of the electrolytic film, wherein the reforming part has a reforming reaction region through which the fuel to be reformed passes and is reacted with the hydrogen atoms supplied by the hydrogen permeable membrane so as to be reformed to the reducing agent, the hydrogen permeable membrane dissociates the hydrogen molecules supplied to the first surface from the hydrogen supply means into hydrogen atoms and makes the hydrogen atoms permeate from the first surface to the second surface to produce the hydrogen atoms on the second surface, the electrolytic film has said first surface and a second surface opposite thereto, the second surface of the electrolytic film faces the first surface of the hydrogen permeable membrane, the water supply means supplies moisture contained in the exhaust gas of the internal combustion engine to the first surface of the electrolytic film, and when electric current is passed through the electrolytic film, the water supplied from the water supply means is decomposed on the first surface of the electrolytic film through electrolysis to produce hydrogen molecules on the second surface of the electrolytic film and the hydrogen molecules are supplied to the first surface of the hydrogen permeable membrane. 12. The exhaust gas control system as in claim 11, wherein the reforming part is arranged in a fuel tank in which the fuel for the internal combustion engine is stored, or next to the fuel tank. 13. The exhaust gas control system as in claim 11, further comprising a heating means for heating the hydrogen permeable membrane. 14. The exhaust gas control system as in claim 13, wherein the heating means heats the hydrogen permeable membrane by using the exhaust gas. 15. The exhaust gas control system as in claim 13, wherein the heating means is a cooling water piping, through which cooling water for cooling the internal combustion engine passes, and heats the hydrogen permeable membrane by using the cooling water. 16. The exhaust gas control system as in claim 11, further comprising a muffler for muffling sound in the exhaust gas passage, wherein the reforming part and the hydrogen permeable membrane are arranged on a downstream side of the reducing catalyst and on an upstream side of the muffler. 17. An exhaust gas control system for an internal combustion engine, the system comprising: an exhaust gas passage through which exhaust gas exhausted from the engine flows; a reducing catalyst part, located in the exhaust gas passage, for selectively reducing nitrogen oxide in the exhaust gas; a reforming part that subjects fuel used for the engine to a reforming reaction to form a reducing agent to be supplied to the reducing catalyst; an inlet passage for flowing fuel into the reforming part; an outlet passage for flowing reducing agent to the reducing catalyst part in the exhaust gas passage, an oxygen supply means for supplying oxygen to the reforming part; a hydrogen permeable membrane for supplying hydrogen atoms to the reforming part, the hydrogen permeable membrane having a first surface and a second surface; and a hydrogen supply means for supplying hydrogen molecules to the first surface of the hydrogen permeable membrane, the hydrogen supply means having an electrolytic film through which electric current passes and water supply means for supplying water to a first surface of the electrolytic film, wherein the reforming part has a reforming reaction region through which the fuel to be reformed passes and is reacted with the hydrogen atoms and the oxygen so as to be reformed to the reducing agent, the hydrogen permeable membrane dissociates the hydrogen molecules supplied to the first surface from the hydrogen supply means into hydrogen atoms and makes the hydrogen atoms permeate from the first surface to the second surface to produce the hydrogen atoms on the second surface, the electrolytic film has said first surface and a second surface opposite thereto, the second surface of the electrolytic film faces the first surface of the hydrogen permeable membrane, the water supply means supplies moisture contained in the exhaust gas of the internal combustion engine to the first surface of the electrolytic film, and when electric current is passed through the electrolytic film, the water supplied from the water supply means is decomposed on the first surface of the electrolytic film through electrolysis to produce hydrogen molecules on the second surface of the electrolytic film and the hydrogen molecules are supplied to the first surface of the hydrogen permeable membrane.
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