(i) In a ceramic catalyst body which comprises a ceramic carrier which has a multitude of pores capable of supporting a catalyst directly on the surface of a substrate ceramic and a catalyst supported on the ceramic carrier, a layer containing an anti-evaporation metal such as Rh is formed on the ou
(i) In a ceramic catalyst body which comprises a ceramic carrier which has a multitude of pores capable of supporting a catalyst directly on the surface of a substrate ceramic and a catalyst supported on the ceramic carrier, a layer containing an anti-evaporation metal such as Rh is formed on the outer surface of catalyst metal particles such as Pt or Rh. The layer containing the anti-evaporation metal protects the catalyst metal and prevents evaporation thereof, thereby suppressing the deterioration; and/or (ii) A ceramic catalyst body is made by having a main catalyst component and a promoter component directly on a ceramic carrier which can directly support the catalyst by substituting a part of the constituent elements of cordierite, and a trap layer is provided in the upstream thereof for trapping sulfur which is a catalyst poisoning component included in the exhaust gas. Since sulfur included in the exhaust gas can be collected by the trap layer, the catalyst poisoning component can be removed from the gas which enters the catalyst, thus preventing catalyst poisoning.
대표청구항▼
What is claimed is: 1. A ceramic catalyst body comprising a ceramic carrier capable of supporting a catalyst component directly on the surface of a ceramic substrate having a crystal lattice and a catalyst supported on the ceramic carrier, wherein catalyst particles are provided with a layer contai
What is claimed is: 1. A ceramic catalyst body comprising a ceramic carrier capable of supporting a catalyst component directly on the surface of a ceramic substrate having a crystal lattice and a catalyst supported on the ceramic carrier, wherein catalyst particles are provided with a layer containing an anti-evaporation metal formed at least in part of an outer surface thereof, wherein one or more of the elements that constitute the ceramic substrate is substituted with an element other than a constituent element, and the ceramic carrier is capable of supporting a catalyst metal directly on the substituting element. 2. The ceramic catalyst body according to claim 1, wherein the layer containing the anti-evaporation metal covers at least 10% of the outer surface of the catalyst metal particles. 3. The ceramic catalyst body according to claim 1, wherein the layer containing the anti-evaporation metal covers at least 50% of the outer surface of the catalyst metal particles. 4. The ceramic catalyst body according to claim 1, wherein the anti-evaporation metal is supported on the outer surface of the catalyst metal particles in the form of a metal, an oxide of the metal or an alloy. 5. The ceramic catalyst body according to claim 1, wherein the catalyst metal is a noble metal and the anti-evaporation metal is a high-melting point metal of which oxide has a melting point of 1,100째 C. or higher. 6. The ceramic catalyst body according to claim 1, wherein the anti-evaporation metal has catalytic activity. 7. The ceramic catalyst body according to claim 1, wherein at least one metal selected from the group consisting of Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Rh, Ta, W and Ir is used as the anti-evaporation metal. 8. The ceramic catalyst body according to claim 1, wherein the catalyst metal is supported on the substituting element by chemical bonding. 9. The ceramic catalyst body according to claim 1, wherein the substituting element is one or more element having a d or an f orbit in the electron orbits thereof. 10. A ceramic catalyst body comprising a ceramic carrier capable of supporting a catalyst component directly on the surface of a ceramic substrate having a crystal lattice and a catalyst supported on the ceramic carrier, wherein catalyst particles are provided with a layer containing an anti-evaporation metal formed at least in part of an outer surface thereof, wherein the ceramic carrier has a multitude of pores capable of directly supporting the catalyst on the surface of the ceramic substrate so that a catalyst metal can be supported directly in the pores, and wherein one or more of the elements that constitute the ceramic substrate is substituted with an element other than a constituent element, and the ceramic carrier is capable of supporting the catalyst metal directly on the substituting element. 11. The ceramic catalyst body according to claim 10, wherein the pores comprise at least one kind selected from the group consisting of defects in the ceramic crystal lattice, microscopic cracks in the ceramic surface and defects in the elements which constitute the ceramic. 12. The ceramic catalyst body according to claim 11, wherein the microscopic cracks measure 100 nm or less in width. 13. The ceramic catalyst body according to claim 11, wherein the pores have diameter or width 1,000 times the diameter of the catalyst ion to be supported therein, or smaller, and the density of pores is 1횞1011 /L or higher. 14. The ceramic catalyst body according to claim 11, wherein the ceramic substrate includes cordierite as the main component, and the pores comprise defects formed by substituting a part of the constituent elements of the cordierite with a metal element having different value of valence. 15. The ceramic catalyst body according to claim 14, wherein the defects comprise at least one of an oxygen defect or a lattice defect, and the density of cordierite crystal containing at least one defect in a unit crystal lattice of cordierite is set to 4횞10-6% or higher. 16. The ceramic catalyst body according to claim 10, wherein the layer containing the anti-evaporation metal covers at least 10% of the outer surface of the catalyst metal particles. 17. The ceramic catalyst body according to claim 10, wherein the layer containing the anti-evaporation metal covers at least 50% of the outer surface of the catalyst metal particles. 18. The ceramic catalyst body according to claim 10, wherein the anti-evaporation metal is supported on the outer surface of the catalyst metal particles in the form of a metal, an oxide of the metal or an alloy. 19. The ceramic catalyst body according to claim 10, wherein the catalyst metal is a noble metal and the anti-evaporation metal is a high-melting point metal of which oxide has a melting point of 1,100째 C. or higher. 20. The ceramic catalyst body according to claim 10, wherein the anti-evaporation metal has catalytic activity. 21. The ceramic catalyst body according to claim 10, wherein at least one metal selected from the group consisting of Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Rh, Ta, W and Ir is used as the anti-evaporation metal. 22. A ceramic catalyst body comprising a ceramic carrier capable of supporting a catalyst directly on the surface of a ceramic substrate having a crystal lattice and a catalyst component supported on the ceramic carrier, wherein a trapping component which adsorbs a catalyst poisoning component included in the gas to be purified is supported at least at the end face of the carrier in the upstream of the flow of gas to be purified, thereby providing a trap layer that traps the catalyst poisoning component, and wherein one or more of the elements that constitute the ceramic substrate is substituted with an element other than a constituent element, and the ceramic carrier is capable of supporting a catalyst metal directly on the substituting element. 23. A ceramic catalyst body comprising a ceramic carrier capable of supporting a catalyst directly on the surface of a ceramic substrate having a crystal lattice and a catalyst component supported on the ceramic carrier, wherein a trap layer is provided at a position near an end face of the ceramic carrier in an upstream flow direction of gas to be purified so as to trap a catalyst poisoning component included in the gas to be purified, wherein one or more of the elements which constitute the ceramic substrate of the ceramic carrier is substituted with an element other than the constituent element, so that the carrier is capable of supporting the catalyst component directly on the substituting element. 24. The ceramic catalyst body according to claim 23, wherein the catalyst component is supported on the substituting element by chemical bonding. 25. The ceramic catalyst body according to claim 23, wherein the substituting element is one or more element having d or f orbit in the electron orbits thereof. 26. The ceramic catalyst body according to claim 23, wherein the trap layer is formed by supporting a trapping component which adsorbs the catalyst poisoning component on a carrier coated with porous ceramic on the surface thereof. 27. The ceramic catalyst body according to claim 23, wherein the catalyst component includes a main catalyst component made of a noble metal and a promoter component which receives the catalyst poisoning, while the promoter component is used as the trapping component which adsorbs the catalyst poisoning component. 28. The ceramic catalyst body according to claim 23, wherein the ceramic carrier has a shape selected from the group consisting of honeycomb, pellet, powder foam body, fiber and hollow fiber. 29. A ceramic catalyst body comprising a ceramic carrier capable of supporting a catalyst directly on the surface of a ceramic substrate having a crystal lattice and a catalyst component supported on the ceramic carrier, wherein a trap layer is provided at a position near an end face of the ceramic carrier in an upstream flow direction of gas to be purified so as to trap a catalyst poisoning component included in the gas to be purified, wherein the ceramic carrier has a multitude of pores which are capable of supporting the catalyst directly on the surface of the ceramic substrate so that the catalyst component can be supported directly in the pores, and wherein one or more of the elements that constitute the ceramic substrate is substituted with an element other than a constituent element, and the ceramic carrier is capable of supporting a catalyst metal directly on the substituting element. 30. The ceramic catalyst body according to claim 29, wherein the pores comprise at least one kind selected from the group consisting of defects in the ceramic crystal lattice, microscopic cracks in the ceramic surface and defects in the elements which constitute the ceramic. 31. The ceramic catalyst body according to claim 30, wherein the microscopic cracks measure 100 nm or less in width. 32. The ceramic catalyst body according to claim 30, wherein the pores have diameter or width 1,000 times the diameter of the catalyst ion to be supported therein, or smaller, and the density of pores is 1 횞1011/L or higher. 33. The ceramic catalyst body according to claim 30, wherein the ceramic substrate includes cordierite as the main component, and the pores comprise defects formed by substituting a part of the constituent elements of the cordierite with metal element having different value of valence. 34. The ceramic catalyst body according to claim 33, wherein the defects comprise at least one of an oxygen defect or a lattice defect, and the density of cordierite crystal containing at least one defect in a unit crystal lattice of cordierite is set to 4 횞10-6% or higher. 35. The ceramic catalyst body according to claim 29, wherein the trap layer is formed by supporting a trapping component which adsorbs the catalyst poisoning component on a carrier coated with porous ceramic on the surface thereof. 36. The ceramic catalyst body according to claim 29, wherein the catalyst component includes a main catalyst component made of a noble metal and a promoter component which receives the catalyst poisoning, while the promoter component is used as the trapping component which adsorbs the catalyst poisoning component.
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