The present invention relates to a method of producing honeycomb structures wherein at least some of the cells are plugged, which is suitably used, for example, as a dust-collecting filter.
In recent years, ceramic honeycomb structures superior in heat resistance and corrosion resistance have been used as a dust-collecting filter for environmental management (e.g. pollution control), product recovery from high-temperature gas, etc. in various sectors including chemistry, electric power, steel and industrial waste treatment. Ceramic honeycomb structures are suitably used, for example, as a dust-collecting filter for use in a high-temperature, corrosive gas atmosphere such as a diesel particulate filter (DPF) for trapping particulates emitted from a diesel engine.
The honeycomb structure used as the above dust-collecting filter is required to have a constitution low in pressure loss and capable of giving a high trapping efficiency. For the requirements, a honeycomb structure wherein at least some of the cells are plugged, for example, as shown in
A honeycomb structure having above described plugged portions can be obtained by: forming plugged portions by dipping an end face of a honeycomb structure having cells functioning as fluid passages in slurry containing at least ceramic particles and dispersion medium in a container, and pressing the honeycomb structure against an inner bottom surface of the container to force the slurry into at least some of the cells; and bringing out the honeycomb structure having the plugged portions formed therein from the container by, for example, picking up the honeycomb structure directly.
The honeycomb structure produced by the above process, however, has had a problem of yielding defect in the plugged portions.
When the shrunk dent 26 generates, there is an inconvenience of the reduced reliability of the plugged portion 22; when there appears the hole 27 passing through the plugged portion 22, dust and particles leak through the hole 27, when it is used as a dust-collecting filter, it becomes impotent as a filter. Hence, this problem has heretofore been avoided by, as shown in FIG. 3(iv), forcing a ceramic slurry (for formation of plugged portion 22) excessively into the cell 23 to make larger the depth (d) of the plugged portion. When the depth (d) of the plugged portion is made larger, however, the surface area of the partition walls 24 separating the cells 22 from each other, that is, the area of filtration is reduced, which is not preferred.
The present invention has been made in view of the above-mentioned problems of the prior art and aims at providing a method for producing a honeycomb structure capable of effectively inhibiting a problem of generation of shrunk dents or holes passing through the plugged portions.
The present inventors made an intensive study in order to address the above aim. As a result, it was found that the above aim can be addressed by forming an air layer between the inner bottom surface of the container and the plugged portions to separate the inner bottom surface and the plugged portions in advance of bringing out the honeycomb structure having the plugging portion formed therein from the container, then bringing out the honeycomb structure from the container. The present invention has been completed based on this finding. That is, the present invention provides the following process for producing a honeycomb structure.
(1) A method of producing a honeycomb structure comprising the steps of: forming plugged portions by dipping an end face of a honeycomb structure having cells each functioning as a fluid passage in slurry containing at least ceramic particles and dispersion medium in a container, and pressing the honeycomb structure against an inner bottom surface of the container to force the slurry into at least some of the cells; and bringing out the honeycomb structure having the plugged portions formed therein from the container to obtain the honeycomb structure having at least some of the cells being plugged: characterized by forming an air layer between the inner bottom surface of the container and the plugged portions to separate the inner bottom surface and the plugged portions in advance of bringing out the honeycomb structure from the container.
(2) The method of producing a honeycomb structure according to above (1), wherein the plugged portions is formed by masking some of the cells at the end face of the honeycomb structure, dipping masked end face of the honeycomb structure in the slurry in the container, and pressing the honeycomb structure against the inner bottom surface of the container to force the slurry into non-masked cells.
(3) The method of producing a honeycomb structure according to above (1) or (2), wherein after forming the plugged portions, by separating the plugged portions and the inner bottom surface with rotating relatively the end face having the plugged portions and the inner bottom surface of the container, the air layer between the inner bottom surface of the container and the plugged portions is formed to separate the inner bottom surface and the plugged portions in advance of bringing out the honeycomb structure.
(4) The method of producing a honeycomb structure according to above (1) or (2), wherein after forming the plugged portions, by moving a bottom portion of the container in a lateral direction to open a bottom surface of the container, the air layer between the inner bottom surface of the container and the plugged portions is formed to separate the inner bottom surface and the plugged portions in advance of bringing out the honeycomb structure.
(5) The method of producing a honeycomb structure according to above (1) or (2), wherein after forming the plugged portions, by introducing air between the plugged portions and the inner bottom surface of the container, the air layer between the inner bottom surface of the container and the plugged portions is formed to separate the inner bottom surface and the plugged portions in advance of bringing out the honeycomb structure.
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The mode for carrying out the method of producing honeycomb structures of the present invention is specifically described below referring to the accompanying drawings.
In developing the method of producing honeycomb structures of the present invention, the present inventors first investigated the reason why shrunk dents in plugged portions or holes passing through plugged portions are generated. As a results, it was found that when slurry is forced into cells to form plugged portions of a honeycomb structure, and bringing out the honeycomb structure having the plugged portions formed therein from a container by, for example, picking up the honeycomb structure directly by a conventional method, the plugged portions (slurry forced in the cells) and the inner bottom surface of the container form a coherent state, which causes generation of shrunk dents in plugged portions or holes passing through plugged portions.
To be specific, in producing a honeycomb structure having plugged portions, plugged portions 22 are formed by dipping an end face of a honeycomb structure 21 in slurry 28 in a container 29, and pressing the honeycomb structure 21 against an inner bottom surface of the container 29 to force the slurry 28 into at least some of the cells 23 partitioned by partition walls 24 as shown in
Generation of shrunk dents in plugged portions or holes passing through plugged portions as described above is due to picking up of the honeycomb structure from the container in the state where negative pressure is acting on plugging portions. Therefore, to avoid such a situation, the honeycomb structure has only to be brought out from the container after the negative pressure acting on plugging portions is released.
Accordingly, in the present invention, the honeycomb structure is not brought out from the container with the plugged portions and the inner bottom surface of the container forming the coherent state (state in which negative pressure is acting on plugging portions), but the honeycomb structure 1 is brought out from the container 9 after forming an air layer 10 between the plugged portions 2 and the inner bottom surface of the container 9 to separate them in advance as shown in
In the present method, since generation of shrunk dents or the like can be inhibited, it is also possible to make as small as about 1 to 5 mm the depth of plugging which has heretofore been as large as about 10 mm (this is larger than necessary). Therefore, plugging of cells 3 can be conducted effectively without decreasing the surface area of partition walls 4 (see
The honeycomb structure produced by the present method is a ceramic honeycomb structure having a plurality of cells each functioning as a passage of a fluid. There is no particular restriction as to the material thereof as long as it is a ceramic. There can be mentioned, for example, one comprising cordierite.
There is no particular restriction as to the shape of a honeycomb structure. There can be mentioned, for example, as shown in
In the present production method, in order to form plugged portions at some of the cells, the other cells may be masked at an end face of the honeycomb structure.
There is no particular restriction as to the process for masking. There can be mentioned, for example, a method of attaching an adhesive film to the whole area of an end face of the honeycomb structure and making holes partially in the adhesive film. Specifically, there can be suitably used, for example, a method of attaching an adhesive film to the whole area of an end face of the honeycomb structure and then making holes, by a laser, only in those areas of the film corresponding to the cells in which plugged portions need be formed. As the adhesive film, there can be suitably used, for example, one obtained by coating an adhesive to one side of a film of resin such as polyester, polyethylene or thermosetting resin.
In a production method of the present invention, as shown in
In the embodiment shown in
There is no particular restriction as to the process for forcing the slurry into the cells. There can be mentioned, for example as shown in
The slurry can be produced by mixing at least a ceramic powder with a dispersion medium (e.g. water). Also, additives such as binder, deflocculant and the like may be added as necessary. As to the material for the ceramic powder, there is no particular restriction and, for example, cordierite can be suitably used. As the binder, a resin such as polyvinyl alcohol (hereinafter referred to as “PVA”) can be used. And, use of a heat-gelling binder which gelates when heated, is preferred. The heat-gelling binder gelates when heated and restrains the particles of the ceramic powder; therefore, it is effective for inhibiting generation of shrunk dents. As the heat-gelling binder, methyl cellulose can be suitably used.
Incidentally, the viscosity of the slurry is generally 5 to 50 Pa·s, and preferably 10 to 20 Pa·s. When the viscosity of the slurry is too low, shrunk dents tend to generate easily, which is not preferred. Meanwhile, when the viscosity of the slurry is too high, the flow resistance of the slurry against cell wall is high and the difference in stuffing speed of slurry between the cell wall vicinity and the cell center is large. Specifically describing, the depth of plugging is smaller at the cell wall vicinity than at the cell center, and the area of contact between the honeycomb structure (cell wall) and the plugging material becomes smaller, which is not preferred. The viscosity of the slurry can be controlled by, for example, the ratio of the ceramic powder to the dispersion medium (e.g. water) or the amount of the deflocculant used.
Then, as shown in
The first method is, as shown in
The second method is, as shown in
The third method is, as shown in
After the air layer is formed between plugged portions and the inner bottom surface of the container in advance to separate them from each other, the honeycomb structure 1 having the plugged portions 2 formed therein may be brought out from the container 9 as shown in
Generally, after forming the plugged portion in the honeycomb structure as described above, the plugged portions are dried, and then the whole honeycomb structure including the plugged portions is subjected to firing.
The present invention is described more specifically below by way of Examples. However, the present invention is in no way restricted by these Examples.
In the following Examples and Comparative Examples, there were used cordierite honeycomb structures each having cells functioning as fluid passages. This honeycomb structure was produced by subjecting clay having an appropriately controlled viscosity to extrusion using an extrusion die having the above-mentioned cell shape, partition wall thickness and cell density, drying the resulting extrudate, then cutting the dried extrudate at both end faces to make them flat.
At an end face of the above honeycomb structure, some of the cells were masked in order to alternately plug adjacent cells (that is, to plugg cells checkerwise). As the masking method, there was used a method of attaching an adhesive film to the whole area of the end face of the honeycomb structure and then making holes, by a laser, in the film areas corresponding to the cells in which plugged portions need be formed. As the adhesive film, there was used a commercial adhesive film (a film obtained by coating an adhesive on one side of a resin film).
Plugged portions were formed by dipping the masked end face of the honeycomb structure in slurry in the container, and the honeycomb structure was pressed against an inner bottom surface of the container to force the slurry into the cells without being masked. At this time, slurry was put in the container so as to have a flat surface and a depth of 5 mm (this depth corresponds to the depth of plugged portions). The honeycomb structure was pressed into the container with the masked end face facing the bottom of the container (perpendicularly to the surface of the slurry) with applying a pressure of 0.05–0.5 MPa, preferably 0.1–0.2 MPa, to dip the masked end face of the honeycomb structure in the slurry.
In the Examples described hereinbelow, after pressing the above honeycomb structure against an inner bottom surface of the container, by opening a bottom surface of the container by moving a bottom portion of the container in a lateral direction, the air layer is formed between the plugged portions and a bottom surface of the container to separate them from each other, and then, the honeycomb structure having plugged portions formed therein was brought out from the container (the second method of the present invention described above). On the other hand, in the Comparative Examples, after pressing the above honeycomb structure against an inner bottom surface of the container, by drawing up the honeycomb structure dipped in the slurry in the container, the honeycomb structure having plugged portion formed therein was brought out from the container (conventional method).
Incidentally, as the above slurry, there was used slurry produced by mixing a cordierite powder as a ceramic powder, methyl cellulose as a heat-gelling binder, and a high-molecular surfactant as a deflocculant, at a ratio shown in Tables 1 to 4, adding thereto water as a dispersion medium, and mixing the resulting material for 30 minutes. The slurry was set for the viscosity of 16 Pa·s.
Finally, the plugged portions formed were dried by hot air oven to obtain a honeycomb structure. In the following Examples and Comparative Examples, plugged portions were formed by a method of the present invention and a conventional method. When evaluations of the honeycomb structures for generation of shrunk dents were given, shapes of the honeycomb structures, kinds and thickness of the adhesive films used for masking, shapes of the cells of the honeycomb structures, and methods for forcing the slurry into the cells were appropriately varied to confirm influences of these factors.
Evaluations were conducted by following method. There were produced fifty honeycomb structures in each of the Examples and Comparative Examples by the methods in Examples and Comparative Examples. The number of cells having shrunk dents in each honeycomb structure was visually observed, and frequency in generation of shrunk dents of each honeycomb structure was culculated according as the following formula (1), followed by culculating the average of the frequency in generation of shrunk dents in the fifty honecomb structures. Evaluations were given with the average being defined as frequency in generation of shrunk dents in each of Examples and Comparative Examples. Incidentally, the number of plugged cells is half the number of whole cells (because cells were alternately plugged checkerwise).
Frequency in generation of shrunk dents (%)=(Number of cells having shrunk dents/Number of whole plugged cells )×100 (1)
In Example 1 and Comparative Example 1, plugged portions were formed by the second method of the present invention and a conventional method, respectively. When evaluations of the honeycomb structures for generation of shrunk dents were given, shapes of the honeycomb structures were appropriately varied to confirm influences of the shapes.
In Example 1 and Comparative Example 1, honeycomb structures having the three kinds of shapes mentioned below were used. {circle around (1)} Cylindrical honeycomb structure (
An adhesive film used for masking was made of polyester and had a thickness of 0.05 mm. Slurry was forced into the cells in such a manner that the honeycomb structure was disposed on the upper side and the container was disposed on the lower side and that a pressure was applied from the honeycomb structure side (referred to as “method A” in Tables).
As a result, as shown in Table 1, frequency in generation of shrunk dents, which was about 15–23% in Comparative Example 1 (conventional method), was reduced to about 1–3% in Example 1 (second method of the present invention). This tendency was the same regardless of shape of honeycomb structures. That is, in all the honeycomb structures of three kinds of shapes mentioned above, frequency in generation of shrunk dents was reduced to about 1–3%.
In Example 2 and Comparative Example 2, plugged portions were formed by the second method of the present invention and a conventional method, and kind and thickness of adhesive films used for masking were appropriately varied upon giving evaluation for the state of generation of shrunk dents, and thereby influence of kind and thickness of adhesive films used for masking was confirmed.
In Example 2 and Comparative Example 2, cylindrical honeycomb structures having a circular bottom having a diameter of 144 mm and a length of 150 mm, a square cell shape, a partition wall thickness of 300 μm, cell density of 300/in2, total number of cells of 7500 were used as in the Example 1-1.
Four kinds of adhesive films having the following materials and thicknesses were used for masking. {circle around (1)} thermosetting resin film having a thickness of 3 mm (Example 2-1, Comparative Example 2-1) {circle around (2)} thermosetting resin film having a thickness of 1.5 mm (Example 2-2, Comparative Example 2-2) {circle around (3)} polyester film having a thickness of 0.05 mm (Example 2-3, Comparative Example 2-3) {circle around (4)} polyester film having a thickness of 0.025 mm (Example 2-4, Comparative Example 2-4). Slurry was forced into the cells in such a manner that the honeycomb structure was disposed on the upper side and the container was disposed on the lower side and that a pressure was applied from the honeycomb structure side (referred to as “method A” in Table).
As a result, as shown in Table 2, frequency in generation of shrunk dents, which was about 15–24% in Comparative Example 2 (conventional method), was reduced to about 1–3% in Example 2 (second method of the present invention). This tendency was the same regardless of shape of kind and thickness of the adhesive films used for masking. That is, in all the adhesive films of various materials and thicknesses mentioned above, frequency in generation of shrunk dents was reduced to about 1–3%.
In Example 3 and Comparative Example 3, plugged portions were formed by the second method of the present invention and a conventional method, and shape of cells of the honeycomb structures were appropriately varied upon giving evaluation for the state of generation of shrunk dents, and thereby influence of shapes of cells of the honeycomb structures was confirmed.
In Example 3 and Comparative Example 3 were used the honeycomb structures having a cylindrical bottom having a circular bottom having a diameter of 144 mm and a length of 150 mm and cells having the shapes described below.
Honeycomb structures each having cells having one of the following three kinds of shapes were used. {circle around (1)} square cell (
As in Example 2-3, polyester adhesive films having a thickness of 0.05 mm were used for masking. Incidentally, since it is impossible to alternately plug adjacent cells (i.e. to plug checkerwise) in the case that cells have a hexagonal shape, plugged portions 2b were formed in a striped pattern as shown in
As a result, as shown in Table 3, frequency in generation of shrunk dents, which was about 15–23% in Comparative Example 3 (conventional method), was reduced to about 1–3% in Example 3 (second method of the present invention). This tendency was the same regardless of shape of the cells of the honeycomb structures. That is, in all the honeycomb structures having cells of shapes mentioned above, frequency in generation of shrunk dents was reduced to about 1–3%.
In Example 4 and Comparative Example 4, plugged portions were formed by the second method of the present invention and a conventional method, and methods of forcing slurry into cells were appropriately varied upon giving evaluation for the state of generation of shrunk dents, and thereby influence of methods of forcing slurry into cells was confirmed.
In Example 4 and Comparative Example 4, cylindrical honeycomb structures having a circular bottom having a diameter of 144 mm and a length of 150 mm, a square cell shape, a partition wall thickness of 300 μm, cell density of 300/in2, total number of cells of 7500 were used as in the Example 1-1. As in Example 2-3, polyester adhesive films having a thickness of 0.05 mm were used for masking.
Forcing slurry into cells were conducted by the following four kinds of methods. {circle around (1)} The honeycomb structure was disposed on the upper side, the container was disposed on the lower side, and pressure was applied from the honeycomb structure side (ref.
As a result, as shown in Table 4, frequency in generation of shrunk dents, which was about 15–17% in Comparative Example 4 (conventional method), was reduced to about 1–3% in Example 4 (second method of the present invention). This tendency was the same regardless of method of forcing slurry into cells. That is, in all the methods of forcing slurry into cells mentioned above, frequency in generation of shrunk dents was reduced to about 1–3%.
As described above, in a method of the honeycomb structure, plugged portions are formed by pressing an end face of the honeycomb structure against an inner bottom surface of the container to force the slurry into cells, and then forming an air layer between the inner bottom surface of the container and the plugged portions to separate them from each other in advance before bringing out the honeycomb structure from the container. Therefore, a method of the present invention can effectively inhibit generation of shrunk dents or holes passing through the plugged portions.
Number | Date | Country | Kind |
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2002-187624 | Jun 2002 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP03/08147 | 6/26/2003 | WO | 00 | 11/18/2004 |
Publishing Document | Publishing Date | Country | Kind |
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WO2004/002607 | 1/8/2004 | WO | A |
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A 9-25180 | Jan 1997 | JP |
Number | Date | Country | |
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20050221014 A1 | Oct 2005 | US |