초록 ▼

A method for rigidifying a fiber-based paper substrate for use in the exhaust system of a combustion device. In the method, a green ceramic fiber-based paper substrate is impregnated with an impregnating dispersion. The impregnated substrate is then dried, calcined and fired to form a rigidified sub

A method for rigidifying a fiber-based paper substrate for use in the exhaust system of a combustion device. In the method, a green ceramic fiber-based paper substrate is impregnated with an impregnating dispersion. The impregnated substrate is then dried, calcined and fired to form a rigidified substrate that is suitable for use in the exhaust system of a combustion device. This rigidification process is performed at least once and, preferably, two or more times. The green paper substrate comprises two or more sheets of green ceramic fiber-based paper, with at least one creased sheet and another sheet being a laminated together to form a plurality of tubular channels. The rigidified substrate comprises refractory ceramic fibers in the form of a ceramic fiber-based paper and agglomerates of ceramic particles. The ceramic particle agglomerates are bonded to and disposed so as to thereby bond together the refractory ceramic fibers at spaced locations along and at intersections of the refractory ceramic fibers so that the refractory ceramic fibers retain much of their original flexibility while in the paper.

대표청구항 ▼

The invention claimed is: 1. Chemically stabilized β-cristobalite comprising pyrolyzed montmorillonite, wherein said chemically stabilized β-cristobalite is stable below about 265�� C. 2. A method of making a chemically stabilized β-cristobalite according to claim 1, said method co

The invention claimed is: 1. Chemically stabilized β-cristobalite comprising pyrolyzed montmorillonite, wherein said chemically stabilized β-cristobalite is stable below about 265�� C. 2. A method of making a chemically stabilized β-cristobalite according to claim 1, said method comprising: heating montmorillonite to a firing temperature and for a time sufficient to convert the montmorillonite to chemically stabilized β-cristobalite, wherein the chemically stabilized β-cristobalite is stable below about 265��C. 3. The method according to claim 2, wherein said heating is at a temperature of about 900�� C. 4. The method according to claim 2, further comprising: introducing the montmorillonite into a sol-gel composition or mixed dispersion before said heating. 5. The method according to claim 3, further comprising: introducing the montmorillonite into a sol-gel composition or mixed dispersion before said heating. 6. The method according to claim 2, further comprising: combining montmorillonite with glass precursor material, wherein said heating further comprises beating the combination of montmorillonite and glass precursor materials to a temperature and for a time sufficient to convert the combination of montmorillonite and glass precursor material to a chemically stabilized β cristobalite glass. 7. The method according to claim 3, further comprising: combining montmorillonite with glass precursor material, wherein said heating further comprises heating the combination of montmorillonite and glass precursor materials to a temperature and for a time sufficient to convert the combination of montmorillonite and glass precursor material to a chemically stabilized β cristobalite glass. 8. The method according to claim 4, further comprising: combining montmorillonite with glass precursor material, wherein said heating further comprises heating the combination of montmorillonite and glass precursor materials to a temperature and for a time sufficient to convert the combination of montmorillonite and glass precursor material to a chemically stabilized β cristobalite glass. 9. The method according to claim 5, further comprising: combining montmorillonite with glass precursor material, wherein said heating further comprises heating the combination of montmorillonite and glass precursor materials to a temperature and for a time sufficient to convert the combination of montmorillonite and glass precursor material to a stabilized β cristobalite glass. 10. The method according to claim 2, wherein the montmorillonite includes a calcium montmorillonite. 11. The method according to claim 3, wherein the montmorillonite includes a calcium montmorillonite. 12. The method according to claim 4, wherein the montmorillonite includes a calcium montmorillonite. 13. The method according to claim 6, wherein the montmorillonite includes a calcium montmorillonite. 14. The method according to claim 10, wherein the calcium montmorillonite has been ion-exchanged with other cations, and said heating further comprises heating the ion-exchanged montmorillonite to a temperature and for a time sufficient to convert the ion-exchanged montmorillonite to a chemically stabilized β cristobalite having a composition that is different than a chemically stabilized β cristobalite formed from calcium montmorillonite that has not be ion-exchanged with other cations. 15. The method according to claim 2, wherein the montmorillonite has been ion-exchanged, and said heating further comprises heating the ion-exchanged montmorillonite to a temperature and for a time sufficient to convert the ion-exchanged montmorillonite to a chemically stabilized β cristobalite having a composition that is different than a chemically stabilized β-cristobalite formed from montmorillonite that has not be ion-exchanged. 16. The method according to claim 2, wherein the chemically stabilized β-cristobalite is stable at room temperature. 17. The method according to claim 2, further comprising: combining the montmorillonite with a glass precursor material, before said heating, wherein the chemically stabilized β-cristobalite is a chemically stabilized β-cristobalite glass. 18. The chemically stabilized β-cristobalite according to claim 1, wherein said chemically stabilized β-cristobalite has a lattice structure and comprises a sufficient level of non-silicone cations substituted and stuffed into said lattice structure such that said chemically stabilized β-cristobalite is stable at room temperature. 19. The chemically stabilized β-cristobalite according to claim 1, wherein said chemically stabilized β-cristobalite acts as a basic oxide. 20. The chemically stabilized β-cristobalite according to claim 1, wherein said chemically stabilized β-cristobalite is a chemically stabilized β-cristobalite glass comprising said pyrolyzed montmorillonite in combination with a pyrolyzed glass precursor material. 21. A ceramic body comprising the chemically stabilized β-cristobalite according to claim 1. 22. The ceramic body according to claim 21, wherein said ceramic body is a ceramic fiber-based paper comprising: ceramic fibers; and agglomerates of ceramic particles bonded to and disposed so as to thereby bond together said ceramic fibers, said agglomerates of ceramic particles comprising said chemically stabilized β-cristobalite. 23. A rigidified ceramic fiber-based paper substrate suitable for use in an exhaust system of a combustion device, said paper substrate comprising: a ceramic fiber-based paper according to claim 22, wherein said ceramic fibers comprise refractory ceramic fibers. 24. The rigidified ceramic fiber-based paper substrate as set forth in claim 23, wherein said montmorillonite clay is a calcium montmorillonite clay. 25. The rigidified paper substrate as set forth in claim 23, wherein lenticular or plate-like pores are present inside said paper, with said pores being aligned close to parallel with the plane of said paper. 26. The rigidified paper substrate as set forth in claim 25, wherein said pores have long axes in the range of from about 50 to about 300 micrometers in length and in the range of from about 10 to about 50 micrometers in height. 27. The rigidified paper substrate as set forth in claim 23, wherein said substrate is at least one of a wall-flow substrate and a flow-through substrate. 28. The rigidified paper substrate as set forth in claim 23 in combination with a mounting material and a housing, wherein said substrate is at least one of a wall-flow substrate and a flow-through substrate, said substrate is disposed in said housing, and said mounting material is positioned between said substrate and said housing so as to form a substrate assembly. 29. The substrate assembly as set forth in claim 28 in combination with a combustion device having an exhaust system, wherein said substrate assembly is disposed in said exhaust system. 30. The rigidified paper substrate as set forth in claim 23, wherein said substrate is at least one of a filter element and a catalyst support suitable for use in an internal combustion engine exhaust system. 31. The rigidified paper substrate as set forth in claim 23, wherein greater than about 60% of said refractory ceramic fibers in said paper are aligned within about 35�� of being parallel with the plane of said paper. 32. The rigidified paper substrate as set forth in claim 23, further comprising a durable ceramic coating disposed so as to harden an exterior surface of said substrate against exposure to exhaust gases passing through said substrate that contact said exterior surface, when said substrate is used in an exhaust system of a combustion device. 33. The rigidified paper substrate as set forth in claim 23, further comprising a durable ceramic coating disposed so as to increase the crush strength of an exterior surface of said substrate, wherein said exterior surface is exposed to mounting pressures, when said substrate is mounted in an exhaust system of a combustion device. 34. The rigidified paper substrate as set forth in claim 23, wherein said substrate is at least an exhaust gas filter, and said substrate is able to filter out greater than about 97% of exhaust particulate having a diameter of less than 150 nms. 35. The rigidified paper substrate as set forth in claim 23, wherein said refractory ceramic fibers have exposed surfaces between said agglomerates of ceramic particles.