This invention provides a molded three-dimensional insulator that is suitable for use in an end cone region of a pollution control device. The invention also provides a method of making the insulator. The insulator includes ceramic fibers that have a bulk shrinkage no greater than 10 weight percent.
This invention provides a molded three-dimensional insulator that is suitable for use in an end cone region of a pollution control device. The invention also provides a method of making the insulator. The insulator includes ceramic fibers that have a bulk shrinkage no greater than 10 weight percent. The ceramic fibers contain alumina and silica and are microcrystalline, crystalline, or a combination thereof.
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1. An end cone insulator comprising (a) ceramic fibers having a bulk shrinkage no greater than 10 percent using the Thermal Mechanical Analyzer test, (b) an organic binder, and (c) no greater than 40 weight percent of an inorganic binder based on a weight of the ceramic fibers, wherein said end cone
1. An end cone insulator comprising (a) ceramic fibers having a bulk shrinkage no greater than 10 percent using the Thermal Mechanical Analyzer test, (b) an organic binder, and (c) no greater than 40 weight percent of an inorganic binder based on a weight of the ceramic fibers, wherein said end cone insulator has a seamless one piece truncated cone-shape that is self-supporting so as to maintain said truncated cone-shape without collapsing or deforming when placed on a flat surface, flexible so that it can be bent and flexed gently without breaking apart or cracking, non-intumescent, and dimensioned with a truncated cone-shape suitable for being disposed between inner and outer cone-shaped metal end cone housings in an end cone region of a pollution control device. 2. The end cone insulator of claim 1, further comprising a cone-shaped metal end cone housing of a pollution control device attached to an inner surface of the end cone insulator, attached to an outer surface of the end cone insulator, or a combination thereof. 3. The end cone insulator of claim 1, wherein the ceramic fibers comprise Al2O3 in an amount of at least 20 weight percent and SiO2 in an amount of at least 30 weight percent based on the weight of the ceramic fibers. 4. The end cone insulator of claim 3, wherein said end cone insulator has a thickness with a compressibility value no greater than 750 kN/m2 when the mount density is about 0.4 g/ml. 5. The end cone insulator of claim 1, wherein the ceramic fibers have a bulk shrinkage no greater than 6 percent. 6. The end cone insulator of claim 1, wherein the ceramic fibers have a bulk shrinkage in the range of 0.5 to 5 percent. 7. The end cone insulator of claim 6, wherein said end cone insulator has a thickness with a compressibility value no greater than 300 kN/m2 when the mount density is about 0.4 g/ml. 8. A pollution control device comprising: a housing comprising an inlet and an outlet, and said inlet comprising an inner cone-shaped metal end cone housing and an outer cone-shaped metal end cone housing defining a gap therebetween;a pollution control element mounted within said housing;a mounting mat disposed between said housing and said pollution control element; andan end cone insulator, according to claim 1, having a thickness and being sandwiched within the gap between said inner and outer cone-shaped metal end cone housings, with the thickness of said end cone insulator having a compressibility value no greater than 750 kN/m2, when the mount density is about 0.4 g/ml, and being in a compressed state while said end cone insulator is sandwiched within the gap at room temperature,wherein said end cone insulator has a bulk before and a mount density after being sandwiched within the gap, the mount density is greater than the bulk density, and the thickness of said end cone insulator can be further compressed and the mount density increased without the ceramic fibers of said end cone insulator breaking or disintegrating. 9. A pollution control device comprising a housing and an end cone insulator according to claim 1, said housing having an inlet and an outlet, said inlet comprising an inner cone-shaped metal end cone housing and an outer cone-shaped metal end cone housing defining a gap therebetween, and said end cone insulator being sandwiched between said inner and outer cone-shaped metal end cone housings. 10. A pollution control device comprising a housing and an end cone insulator according to claim 4, said housing having an inlet and an outlet, said inlet comprising an inner cone-shaped metal end cone housing and an outer cone-shaped metal end cone housing defining a gap therebetween, and said end cone insulator being sandwiched between said inner and outer cone-shaped metal end cone housings. 11. A method of making an end cone insulator according to claim 1, said method comprising: preparing an aqueous slurry comprising (a) ceramic fibers having a bulk shrinkage no greater than 10 percent using the Thermal Mechanical Analyzer test, (b) an organic binder, and (c) no greater than 40 weight percent of an inorganic binder based on a weight of the ceramic fibers;vacuum forming a seamless one piece truncated cone-shaped preform from the aqueous slurry on a permeable forming cone-shaped die;drying the preform to produce an end cone insulator,wherein the end cone insulator has a seamless one piece truncated cone-shape that is being self-supporting so as to maintain the truncated cone-shape without collapsing or deforming when placed on a flat surface, flexible so that it can be bent and flexed gently without breaking apart or cracking, non-intumescent, and dimensioned with a truncated cone-shape suitable for being disposed between inner and outer cone-shaped metal end cone housings in an end cone region of a pollution control device. 12. The method of claim 11, wherein said vacuum forming further comprises: inserting the preform into or onto a cone-shaped shape-retaining device while the preform is supported by the permeable forming cone-shaped die,transferring the preform to the cone-shaped shape-retaining device, andremoving the permeable forming cone-shaped die. 13. The method of claim 12, wherein the shape-retaining device is an inner cone-shaped metal end cone housing or an outer cone-shaped metal end cone housing of an end cone region of a pollution control device. 14. The method of claim 13, wherein the end cone insulator is attached to the end cone housing. 15. The method of claim 11, wherein the ceramic fibers are microcrystalline, crystalline, or a combination thereof, and the end cone insulator has a thickness with a compressibility value no greater than 750 kN/m2 when the mount density is about 0.4 g/ml. 16. The method of claim 11, wherein the ceramic fibers comprise Al2O3 in an amount of at least 20 weight percent and SiO2 in an amount of at least 30 weight percent based on the weight of the ceramic fibers. 17. The method of claim 11, wherein the slurry comprises up to 20 weight percent of the organic binder based on the weight of the end cone insulator. 18. A method of making a pollution control device having an end cone region comprising inner and outer cone-shaped metal end cone housings, said method comprising: disposing an end cone insulator between the inner and outer cone-shaped metal end cone housings of the pollution control device, where the end cone insulator is made according to the method of claim 11. 19. A pollution control device comprising: a housing comprising an inlet and an outlet, and said inlet comprising an inner cone-shaped metal end cone housing and an outer cone-shaped metal end cone housing defining a gap therebetween;a pollution control element mounted within said housing;a mounting mat disposed between said housing and said pollution control element; andan end cone insulator, according to claim 1, having a thickness and being sandwiched within the gap between said inner and outer cone-shaped metal end cone housings, with the thickness of said end cone insulator having a compressibility value no greater than 300 kN/m2, when the mount density is about 0.4 g/ml, and being in a compressed state while said end cone insulator is sandwiched within the gap at room temperature,wherein said end cone insulator has a bulk density in the range of 0.1 to 0.4 g/ml before being sandwiched within the gap and a mount density after being sandwiched within the gap that is greater than the bulk density, and the thickness of said end cone insulator can be further compressed and the mount density increased without the ceramic fibers of said end cone insulator breaking or disintegrating. 20. An end cone insulator comprising (a) ceramic fibers having a bulk shrinkage no greater than 10 percent using the Thermal Mechanical Analyzer test, and (b) a binder, with no greater than 40 weight percent of an inorganic binder based on a weight of the ceramic fibers, wherein said end cone insulator has a seamless one piece truncated cone-shape that is self-supporting so as to maintain said truncated cone-shape without collapsing or deforming when placed on a flat surface, flexible so that it can be bent and flexed gently without breaking apart or cracking, non-intumescent, and dimensioned with a truncated cone-shape suitable for being disposed between inner and outer cone-shaped metal end cone housings in an end cone region of a pollution control device.
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