JP4442625B2 - Exhaust gas purification filter - Google Patents

Description

  The present invention relates to a ceramic exhaust gas purification filter that collects carbon fine particles and the like discharged from an internal combustion engine.

The use of a ceramic honeycomb structure is promising as an exhaust gas purification filter that is regenerated by filtering and burning particulates such as carbon particulates discharged from a diesel engine or the like.
Specifically, as shown in FIG. 3, in the conventional exhaust gas purification filter 9, the cells 90 opened at both end faces of the honeycomb structure are alternately closed by plug portions 95. On both end faces, the plug portions 95 are arranged in a so-called checkered pattern. A catalyst is supported on the surface of the partition wall 98.

  As a result, as shown in the figure, the exhaust gas 8 that has entered the cell 90 passes through the partition wall 98 and is discharged, and particulates and the like contained in the exhaust gas 8 are captured and deposited on the partition wall 98. The accumulated particulates are burned and removed by the catalytic action carried on the partition wall 98, and the exhaust gas purification filter 9 is regenerated as needed.

Incidentally, in order to further improve the purification performance of the exhaust gas purification filter 9, it is effective to further increase the area of the inner surface thereof. For this, various measures have been taken, such as thinning the partition walls of the honeycomb structure constituting the exhaust gas purification filter, reducing the cell pitch, and the like. However, although such a measure mainly for reducing the thickness of the partition wall is effective, there are limitations in that the manufacturing itself is very difficult and the overall strength is lowered.
Therefore, it is considered effective to increase the filter area by using the plug portion 95 as a filter as a measure other than the thinning of the partition wall.

  The present invention has been made in view of such conventional problems, and an object of the present invention is to provide an exhaust gas purification filter that can positively use a plug portion as a filter.

The first invention has a honeycomb shape having a large number of cells surrounded by partition walls, has a plug portion that closes either one of both ends of the cell, and exhaust gas that has entered the cell. In the exhaust gas purification filter configured to capture and deposit the particulates contained in the partition wall, and to deposit and remove the deposited particulates by the action of the catalyst supported on the partition wall,
Both the plug and the partition at both ends of the exhaust gas purification filter are made of a porous material, the porosity of the partition is P1, the porosity of the plug is P2, the average thickness of the partition is t, When the average value of the length of the stopper is L, the M value indicated by the relational expression M = (L / t) × (P1 / P2) is in the range of 10 <M <90,
The plugs at both ends of the exhaust gas purification filter are configured to allow exhaust gas to pass through and to be used as a filter .
In addition, the plug portion is an exhaust gas purification filter characterized in that a PM oxidation catalyst for particulate combustion is supported on the surface of the plug portion .

In the exhaust gas purification filter of the present invention, in particular, the particulates contained in the exhaust gas that has entered the cell are trapped and deposited on the partition walls, and the deposited particulates are burned by the action of the catalyst supported on the partition walls. The present invention relates to an exhaust gas purification filter of the type configured to be removed.
And in the exhaust gas purification filter of this invention, both the said partition and the said plug part are comprised from the porous body. And these porosity and size have a specific relationship.
That is, M = (L / t where P1 is the porosity of the partition wall, P2 is the porosity of the plug portion, t is the average thickness of the partition wall, and L is the average length of the plug portion. ) × (P1 / P2) The M value indicated by the relational expression is in the range of 10 <M <90. Thus, the exhaust gas purification filter can be configured such that the exhaust gas passes through the plug portion while sufficiently securing the strength of the plug portion. Therefore, the plug portion can be used as a filter without reducing the strength, the entire filter area is increased, and the performance of the exhaust gas purification filter as a whole is improved.

  In the present invention, average values are used as the values of t and L. Moreover, as said porosity, the value which calculated | required and measured the pore volume by the mercury intrusion method using a porosimeter can be used. Since the average values are used as the values of t and L, it is not necessary for all the plug portions to have the above requirements. It is sufficient that at least the average value satisfies the range of the M value.

The second invention has a honeycomb shape having a large number of cells surrounded by partition walls, and has a plug portion that closes either one of the two ends of the cell, and exhaust gas that has entered the cell. In the exhaust gas purification filter configured to capture and deposit the particulates contained in the partition wall, and to deposit and remove the deposited particulates by the action of the catalyst supported on the partition wall,
Both the plugs and the partition walls at both ends of the exhaust gas purification filter are made of a porous body, the porosity of the partition walls is P1, the porosity of the plugs is P2, the average thickness of the partition walls is t, When the length of each plug portion is L2, the plug portion in which the M2 value represented by the relational expression M2 = (L2 / t) × (P1 / P2) is within the range of 10 <M2 <90 Is over 50% of the total,
The plugs at both ends of the exhaust gas purification filter are configured to allow exhaust gas to pass through and to be used as a filter .
In addition , in the exhaust gas purification filter, the plug portion carries a PM oxidation catalyst for particulate combustion on the surface thereof .

  In the exhaust gas purification filter of the present invention, the particulates contained in the exhaust gas that has entered the cell are trapped and accumulated in the partition walls, and the deposited particulates are burned and removed by the action of the catalyst supported on the partition walls. The present invention relates to an exhaust gas purification filter of the type configured as described above. In the exhaust gas purification filter of the present invention, the P2 and L2 are determined for each of the plug portions, and the M2 value determined by the porosity P1 of the partition walls and the average value t of the partition wall thicknesses is The thing which falls into a specific range is made to occupy 50% or more of the whole stopper part. Also by this, the purification performance improvement by using a plug part as a filter can be obtained similarly to the above.

  In the first invention (invention 1), when the M value is 10 or less, the strength of the plug portion is weak, which may cause a practical problem. On the other hand, when the M value exceeds 90, there is a problem that exhaust gas hardly passes through the plug portion and it is difficult to use the plug portion as a filter.

  The M value is preferably 25 or less (claim 2). In this case, the effect of using the plug portion as a filter can be sufficiently obtained.

In the second invention (invention 3), when the M2 value is less than 50% of the whole plug portion in the range of 10 <M2 <90, There is a problem that a sufficient filter effect cannot be obtained.
In particular, the plug portion having the M2 value of 25% or less is preferably 50% or more of the whole (claim 4). In this case, the effect of the plug portion as a filter can be further enhanced.

  In the first and second inventions (Inventions 1 and 2), it is preferable that an average value of the length of the plug portion is 5 mm or less. When the average value of the length of the plug part exceeds 5 mm, the resistance when exhaust gas passes increases, and the function as a filter may be reduced. Therefore, 3 mm or less is more preferable. On the other hand, if the length of the plug portion is too short, its strength decreases. For this reason, the lower limit value of the average value of the lengths of the plug portions is preferably 0.5 mm.

Moreover, the partition and the plug in the exhaust gas purification filter can be made of, for example, cordierite, mullite, spinel, or other ceramics.
Moreover, the partition and the plug can carry a catalyst for burning the captured particulates. Examples of the type of catalyst include a so-called three-way catalyst, a PM oxidation catalyst, and a NOx storage reduction catalyst.

Example 1
An embodiment of the exhaust gas purification filter of the present invention will be described with reference to FIGS.
As shown in FIGS. 1 and 2, the exhaust gas purification filter 1 of the present example has a honeycomb shape having a large number of cells 10 surrounded by partition walls 11, and closes one of the ends of the cells 10. It has a stopper part 2.

Both the partition wall 11 and the plug portion 2 are made of a porous body. When the porosity of the partition 11 is P1, the porosity of the plug 2 is P2, the average thickness of the partition 11 is t, and the average length of the plug 2 is L, M = (L / t) The M value indicated by the relational expression of × (P1 / P2) is in the range of 10 <M <90.
This will be described in detail below.

In manufacturing the exhaust gas purification filter 1 of this example, first, a ceramic honeycomb structure is manufactured. Therefore, the cordierite raw material that is the raw material is prepared. As the cordierite raw material, a material containing kaolin, aluminum hydroxide, alumina, talc, kaolin, carbon particles or the like is used. The final composition is adjusted so that the main component is cordierite composed of SiO ₂ : 45 to 55 wt%, Al ₂ O ₃ : 33 to 42 wt%, and MgO: 12 to 18 wt%. To do. The porosity is adjusted by adjusting the content of the carbon particles, kaolin, talc, aluminum hydroxide and the like.

Next, after a predetermined amount of the above cordierite raw material and water are kneaded, this is extruded into a honeycomb shape using a honeycomb structure forming mold to obtain a honeycomb structure. Subsequently, the cordierite raw material used as the said plug part 2 is arrange | positioned in a predetermined | prescribed cell edge part. In this example, the stopper 2 is set to be arranged in a so-called checkered pattern. And after drying, it bakes.
Note that various known methods can be employed as a method of arranging the plug portion 2.

  The obtained honeycomb structure (exhaust gas purification filter 1) has # 300 cells and the partition wall 11 has a thickness of 0.2 mm. In this example, the porosity P1 of the partition wall 11 is 55%, the porosity P2 of the plug portion 2 is 70%, the average thickness t of the partition wall 11 is 0.2 mm, and the average length L of the plug portion 2 is L. Is 4 mm. Therefore, the M value is 16.

The exhaust gas purification filter 1 is completed as an exhaust gas purification filter by supporting a particulate oxidation PM oxidation catalyst on the entire surface, that is, the surface of the partition wall 11 and the surface of the plug portion 2.
This exhaust gas purification filter 1 is incorporated in a catalytic converter (not shown) and used as a particulate filter for a diesel engine.

Next, the function and effect of this example will be described.
In the exhaust gas purification filter 1 of this example, both the partition wall 11 and the plug portion 2 are made of a porous body. These porosity and size were in a relationship where the M value was 16. Thereby, when the exhaust gas purification filter 1 is disposed in the exhaust gas flow path, the plug portion 2 can be used as a filter.

  That is, as shown in FIG. 2, the exhaust gas 8 introduced into the cell 10 of the exhaust gas purification filter 1 passes through the partition wall 11 and moves to the adjacent cell, and passes through the plug portion 2. It can be discharged. The particulates contained in the exhaust gas 8 are captured by the partition wall 11 and also by the plug portion 2. The captured particulates are burned and removed by the action of the catalyst supported on the partition wall 11 and the plug portion 2.

Thus, in the exhaust gas purification filter 1 of this example, the filter area is increased as compared with the conventional case, and the surface area of the partition wall 11 and the surface area of the plug portion 2 are combined. Therefore, the purification performance of the exhaust gas purification filter 1 is improved as compared with the prior art.
Moreover, since the said M value exceeds 10, the intensity | strength of the plug part 2 practical can also be ensured.

(Example 2)
In this example, an experiment was performed in which a plurality of honeycomb structures similar to the exhaust gas purification filter 1 of Example 1 were manufactured and the porosity, size, and the like were changed to determine the influence of the M value. In this example, a honeycomb structure was manufactured in the same manner as in Example 1 except that the catalyst was not supported on the honeycomb structure.

Tables 1 and 2 show values of P1, P2, t, and L of the manufactured honeycomb structure.
As shown in these tables, in this example, the porosity P1 of the partition wall 11 is 55 to 70%, the average thickness t of the partition wall 11 is 0.2 mm or 0.3 mm, and the porosity P2 of the plug portion 2 is 10 51 types of honeycomb structures having 70% and an average length L of the plug portion 2 of 2 to 6 mm were prepared.

In Tables 1 and 2, M values indicated by the relational expression M = (L / t) × (P1 / P2) are calculated and described.
In this example, an experiment was conducted to collect 2 g / liter of soot generated from a soot generating device similar to particulates. And the cross section of the plug part 2 of the downstream after an experiment was confirmed with the electron microscope, and the presence or absence of the soot entry into the inside was confirmed. Table ◎ indicates that the intrusion of the kite has been sufficiently confirmed, ◎, can be confirmed for the time being, but is relatively less than in the case of ◎, △ if it has been confirmed slightly, and × if it has not been confirmed at all. 1 and shown in Table 2.

As can be seen from Tables 1 and 2, when the M value exceeds 90, the results of the soot entry test are both x, indicating that the filter effect cannot be exhibited. On the other hand, when the M value is less than 90, it is ◎, ○, or Δ, indicating that the filter effect can be exhibited. Among these, in particular, when M was 25 or less, it was found that sufficient soot entry was observed and the filter effect was high.
In addition, although not clarified in this experiment, when the M value is less than 10, the length L of the plug portion 2 is short and the porosity P2 is large, and the strength of the plug portion 2 is small and put into practical use. Is difficult.

1 is a perspective view of an exhaust gas purification filter in Example 1. FIG. FIG. 3 is an explanatory view showing a cross-sectional structure of an exhaust gas purification filter in Example 1. Explanatory drawing which shows the cross-sectional structure of the exhaust gas purification filter in a prior art example.

Explanation of symbols

1 Exhaust gas purification filter,
10 cells,
11 Bulkhead,
2 stoppers,
8 exhaust gas,

Claims (5)

It has a honeycomb shape having a large number of cells surrounded by partition walls, has a plug portion that closes either one of the ends of the cells, and the particulates contained in the exhaust gas that has entered the cells In the exhaust gas purification filter configured to be captured and deposited by the partition wall, and the deposited particulates are burned and removed by the action of the catalyst supported on the partition wall.
Both the plug and the partition at both ends of the exhaust gas purification filter are made of a porous material, the porosity of the partition is P1, the porosity of the plug is P2, the average thickness of the partition is t, When the average value of the length of the stopper is L, the M value indicated by the relational expression M = (L / t) × (P1 / P2) is in the range of 10 <M <90,
The plugs at both ends of the exhaust gas purification filter are configured to allow exhaust gas to pass through and to be used as a filter .
The plug portion carries an PM oxidation catalyst for particulate combustion on the surface thereof .   The exhaust gas purification filter according to claim 1, wherein the M value is 25 or less. It has a honeycomb shape having a large number of cells surrounded by partition walls, has a plug portion that closes either one of the ends of the cells, and the particulates contained in the exhaust gas that has entered the cells In the exhaust gas purification filter configured to be captured and deposited by the partition wall, and the deposited particulates are burned and removed by the action of the catalyst supported on the partition wall.
Both the plugs and the partition walls at both ends of the exhaust gas purification filter are made of a porous body, the porosity of the partition walls is P1, the porosity of the plugs is P2, the average thickness of the partition walls is t, When the length of each plug portion is L2, the plug portion in which the M2 value represented by the relational expression M2 = (L2 / t) × (P1 / P2) is within the range of 10 <M2 <90 Is over 50% of the total,
The plugs at both ends of the exhaust gas purification filter are configured to allow exhaust gas to pass through and to be used as a filter .
The plug portion carries an PM oxidation catalyst for particulate combustion on the surface thereof .   The exhaust gas purification filter according to claim 3, wherein the plug portion having the M2 value of 25% or less is 50% or more of the whole.   The exhaust gas purification filter according to any one of claims 1 to 4, wherein an average value of the length of the plug portion is 5 mm or less.