초록 ▼

A ceramic wall-flow filter for filtering particulate matter from gases and methods for manufacturing such wall-flow filters are disclosed. The filter includes an array of porous ceramic walls defining a pattern of end-plugged inlet and outlet cells, and heat absorbing elements disposed within at lea

A ceramic wall-flow filter for filtering particulate matter from gases and methods for manufacturing such wall-flow filters are disclosed. The filter includes an array of porous ceramic walls defining a pattern of end-plugged inlet and outlet cells, and heat absorbing elements disposed within at least some of the outlet cells such that a bulk heat capacity of the outlet cells is greater than a bulk capacity of the inlet cells. The heat absorbing elements increase a bulk heat capacity of the filter without substantially interfering with a flow of gas through the porous ceramic walls by allowing thinner walls. According to the method, during the step of extruding or thereafter, heat absorbing elements are formed within at least some of the outlet cells such that a heat capacity of the outlet cells is greater than the inlet cells.

대표청구항 ▼

We claim: 1. A ceramic wall-flow filter, comprising: a filter body having an array of porous ceramic walls defining a pattern of inlet and outlet cells traversing the body and extending between an inlet end and an outlet end, the inlet cells including first plugs at the outlet end, and the outlet c

We claim: 1. A ceramic wall-flow filter, comprising: a filter body having an array of porous ceramic walls defining a pattern of inlet and outlet cells traversing the body and extending between an inlet end and an outlet end, the inlet cells including first plugs at the outlet end, and the outlet cells including second plugs at the inlet end, and heat absorbing elements disposed within at least some of the outlet cells such that a bulk heat capacity of the elements in the outlet cells is greater than a bulk heat capacity of elements in the inlet cells, if any; wherein said heat absorbing elements comprise a porous ceramic foam material. 2. The ceramic wall-flow filter of claim 1 wherein said porous ceramic foam material is a coating applied on inner surfaces of the at least some of the outlet cells. 3. The ceramic wall-flow filter of claim 1 wherein the porous ceramic foam material consists of a non-active material. 4. The ceramic wall-flow filter of claim 1 wherein said ceramic foam material is provided in at least some of said outlet cells only, and not in any of the inlet cells. 5. The ceramic wall-flow filter of claim 1 wherein said ceramic foam material substantially entirely fills at least some of the outlet cells. 6. The ceramic wall-flow filter of claim 1 wherein the permeability of said ceramic foam material is higher than the permeability of the ceramic material forming the porous ceramic walls. 7. A diesel particulate exhaust filter, comprising: a housing, and the ceramic wall-flow filter of claim 1 contained within the housing. 8. A diesel exhaust system, comprising: a diesel particulate exhaust filter including a housing and the ceramic wall-flow filter of claim 1 contained within the housing, an engine, and piping fluidly interconnecting the diesel particulate exhaust filter and the engine. 9. The ceramic wall-flow filter of claim 1 wherein a material, mass, and configuration of the elements are selected to provide an increase in a bulk heat capacity of the filter without substantially interfering with a flow of gas through said porous ceramic walls, as compared with a like constructed filter without said elements. 10. A method of manufacturing a ceramic wall-flow filter, comprising the steps of: forming ceramic material into a filter body having an array of porous ceramic walls defining a pattern of inlet and outlet cells traversing the body and extending between an inlet end and an outlet end, plugging the inlet cells with first plugs at the outlet end, plugging the outlet cells with second plugs at the inlet end, and during the step of forming or thereafter, forming heat absorbing elements within at least some of said outlet cells such that a bulk heat capacity of the outlet cells is greater than a bulk heat capacity of the inlet cells; wherein the heat absorbing elements are comprised of a material selected from the group consisting of ceramics, glasses, metals, carbide materials, and combinations thereof. 11. A ceramic wall-flow filter, comprising: a filter body having an array of porous ceramic walls defining a pattern of inlet and outlet cells traversing the body and extending between an inlet end and an outlet end, the inlet cells including first plugs at the outlet end, and the outlet cells including second plugs at the inlet end, and heat absorbing elements disposed within at least some of the outlet cells such that a bulk heat capacity of the elements in the outlet cells is greater than a bulk heat capacity of elements in the inlet cells, if any; wherein the elements comprise loose material and are not attached to any portion of the porous ceramic walls, wherein the loose material is selected from the group consisting of ceramics, glasses, metals, carbide materials, and combinations thereof. 12. A ceramic wall-flow filter, comprising: a filter body having an array of porous ceramic walls defining a pattern of inlet and outlet cells traversing the body and extending between an inlet end and an outlet end, the inlet cells including first plugs at the outlet end, and the outlet cells including second plugs at the inlet end, and heat absorbing elements disposed within at least some of the outlet cells such that a bulk heat capacity of the elements in the outlet cells is greater than a bulk heat capacity of elements in the inlet cells, if any; wherein said elements comprise webs of porous ceramic material extending into at least some of the outlet cells. 13. The ceramic wall-flow filter of claim 12 wherein said webs extend completely radially across said outlet cells thereby dividing the outlet cell into outlet subcells. 14. The ceramic wall-flow filter of claim 12 wherein an interior of said outlet cells has a generally square radial cross section, and at least some of said webs are connected across two corners of said interior in a diagonal configuration. 15. The ceramic wall-flow filter of claim 12 wherein two of said webs are connected across different opposing corners of said interior in an x-shaped configuration. 16. The ceramic wall-flow filter of claim 12 wherein the thickness of said webs is different from the thickness of the porous ceramic walls. 17. The ceramic wall-flow filter of claim 12 wherein said outlet cells have a square cross section, and wherein the webs are connected to, and extend from opposing midpoints of said porous ceramic walls. 18. The ceramic wall-flow filter of claim 12 wherein said webs are disposed in the outlet cells only.