DE29800038U1 - Honeycomb structure with support sections - Google Patents

Description

10

The present invention relates to a honeycomb body arrangement, in particular for catalyst carrier bodies for the exhaust gas purification of motor vehicles.

with a housing in which a honeycomb body is arranged, which has different radial strengths over its circumference, and with a compensating layer arranged between the housing and the honeycomb body, are known, for example, from the utility model G 74 01 002.

Such αλαθαθαθα have a large number of channels separated from one another by partition walls. The channels have a square, rectangular or other polygonal cross-section. Different cross-sectional shapes are described in US Pat. No. 3,853,485.

Due to the design of the channel geometry and the arrangement of the channels within a cross-sectional area of the honeycomb, such a honeycomb has different strengths distributed over the circumference in the radial direction. These different strengths of the honeycomb also influence the fracture behavior and the elastic behavior of the honeycomb. WO 94/15712 discloses a honeycomb that has a

has increased elasticity, whereby in particular the elasticity properties are not different in different directions. According to the proposal of WO 94/15712, the honeycomb body has partition walls at least in an outer area, which are arranged and shaped in such a way that in the cross-section through the honeycomb body they do not form any rigid structures in the radial direction and/or rigid support structures running in the circumferential direction.

Such a honeycomb body, which is made of a ceramic and/or metallic material, has the advantage that it is not easily destroyed by forces acting on the honeycomb body in the radial direction from a housing, since it has a uniform strength in the radial direction over its circumference.

is The fundamental problem of the destruction of a honeycomb body by forces acting uniformly on the honeycomb body from the housing in a radial direction is solved by WO 94/15712.

Based on this, the invention is based on the object of specifying a honeycomb body arrangement in which damage to a catalyst carrier body with different radial strength properties over its circumference can be avoided by radially directed forces acting from the housing.

According to the invention, this objective is achieved by a honeycomb body arrangement with the features of claim 1. Advantageous further developments and embodiments, which can be used individually or in combination with one another, are the subject of the subclaims.

The invention is based on the idea that the radial strength properties of a honeycomb body, which differ over the circumference, can be used for stable mounting in the housing by appropriately designing a compensating layer arranged between the honeycomb body and a housing. The compensating layer, which is arranged between the housing and the honeycomb body, has at least two support sections in the circumferential direction of the honeycomb body, which exert higher forces on the honeycomb body in the radial direction than those exerted on the honeycomb body outside the support sections in the other circumferential areas.

&iacgr;&ogr;. The supporting sections of the compensation layer are formed in areas of higher radial strength of the honeycomb body. In the areas of the supporting sections, the forces acting from the housing on the honeycomb body are essentially absorbed and introduced into the relatively rigid structure of the honeycomb body. In the other peripheral areas, the

is between two adjacent supporting sections of the compensation layer, only small or no forces are introduced into the honeycomb body. The honeycomb body is supported at at least two points or in two areas in cross-section due to the design of the compensation layer within the housing.

This inventive design of the honeycomb body arrangement ensures that no destruction of the honeycomb body occurs during the manufacture of such a honeycomb body arrangement, i.e. during installation in a housing. A further advantage of this design is that during operation of the honeycomb body arrangement, the forces arising due to thermal expansion are absorbed mainly by the support sections and thus in the most stable directions of the honeycomb body.

The honeycomb body can be a metallic and/or ceramic body. The channel cross-sections can have a relatively simple geometry, which

lead to the formation of direction-dependent radial strengths of the honeycomb body. Typically, the invention is particularly suitable for particularly thin-walled extruded ceramic honeycomb bodies, in particular with square channel cross-sections, in which case a holder in four support sections is preferred, each of which exerts forces on the honeycomb body in the direction of the channel walls.

The different strength of the honeycomb body can be compensated by appropriately selecting the properties of the leveling layer itself.

&iacgr;&ogr; A design of the leveling layer is preferred in which the supporting sections have a higher weight per unit area than the other sections of the leveling layer. In particular, the supporting sections have a higher density than the other sections. This design of the leveling layer allows a different

is deformation behavior of the support sections and the other peripheral areas A higher strength of the support sections can also be achieved by the support sections being at least partially formed by at least one insert.

The insert can have a structure which can be, for example, a sandwich structure, whereby the forces directed from the housing in the radial direction to the honeycomb body are absorbed by the insert.

Alternatively or additionally, the insert can be made of a material that is more strong than the material of the other sections of the leveling layer. The use of a metallic material is preferred here. This insert can also serve as a contact point for an electrical connection if the honeycomb body is to be an electrically heatable honeycomb body.

Preferably, the leveling layer arranged between the honeycomb body and the housing is at least partially mat-shaped, whereby thermal insulation of the honeycomb body from the housing is also achieved. The leveling layer preferably contains at least one mat made of ceramic fibers, with so-called swelling mats preferably being used, which, due to their crystalline structure, can fill cavities by swelling as a result of water absorption.

Compensation for the different strengths in the radial direction &iacgr;&ogr; over the circumference of the honeycomb body can also be achieved by forming the supporting sections by at least two, preferably three, layers of the compensating layer. In this case, the compensating layer is formed in one piece and the layers are formed by folding the compensating layer on top of one another. This possibility opens up a simple and cost-effective implementation of the invention.

According to a further inventive idea, it is proposed that the radial strength properties of a honeycomb body, which vary over the circumference, are compensated by a corresponding design of the housing. For this purpose, the housing has at least two radially inward-facing support segments in the circumferential direction of the honeycomb body, which are formed in areas of higher radial strength of the honeycomb body. In the areas of the support segments, the forces acting from the housing on the honeycomb body are introduced into the areas of the honeycomb body in which the honeycomb body has a higher radial strength. This ensures that the areas of the honeycomb body that have a reduced radial strength do not have to absorb any or only very small forces. In this design, too, there is preferably a compensating layer of fiber mats between the housing and the honeycomb body, which is compressed more strongly at the support segments than in the

remaining circumferential areas, so that supporting sections are formed on the supporting segments.

The support sections can extend over the entire axial length of the honeycomb body. However, this is not absolutely necessary. It can be advantageous, especially for axially elongated honeycomb bodies that are not produced exactly straight, if the support sections only extend over part of the axial length of the honeycomb body, e.g. are only arranged near the end faces. Support sections can also be provided that are distributed over the surface of the honeycomb body. The number and size of the support sections should, however, be such that it is ensured that the honeycomb body is held firmly and durably in the housing.

is According to a further advantageous embodiment of the invention, it is proposed that, in a honeycomb arrangement with an even number of support sections in a cross-section of the honeycomb arrangement, these are arranged in such a way that two support sections are diametrically opposite each other. In any case, the support sections should be evenly distributed over the circumference of the honeycomb.

To simplify the assembly of the honeycomb body arrangement and to ensure that the supporting sections of the compensating layer are arranged in the areas of higher radial strength of the honeycomb body, it is provided that the honeycomb body and/or the compensating layer and/or the housing have a positioning aid. For this purpose, it is proposed in particular that the positioning aid is designed in the form of at least one optical marking, whereby the assembly of a honeycomb body arrangement can also be automated. It is also proposed that

that the positioning aid is formed by a projection or a recess which can then also be mechanically scanned.

According to a further inventive idea, it is proposed that the honeycomb body has at least two curvatures directed radially outwards in cross-section on its side facing the compensating layer, whereby the curvatures are formed in areas of higher radial strength of the honeycomb body. This solution also ensures that the areas of the honeycomb body that have a reduced radial strength

&iacgr;&ogr; no or only very small forces have to be absorbed. In a particularly advantageous manner, the respective curvatures are designed as axially extending flat beads, as this creates an optimal force distribution in the honeycomb body. The curvatures create supporting sections in the compensation layer and, in the case of circular cross-sections of the

is housing and, apart from the curvatures, circular cross-sections of the honeycomb body, that the honeycomb body can be installed in any orientation and the supporting sections always form in the areas of higher radial strength. Axially running beads can be produced during the extrusion of honeycomb bodies by slightly modifying the extrusion cross-section, without any special effort being required.

Further details and advantages of the invention are explained using the embodiments shown in the drawing, to which the invention is not limited. They show:

Fig. 1 shows a first embodiment of a honeycomb body arrangement in

Cross-section,

Fig. 2 shows a first embodiment of a support section of a

equal layer in cross section,

Fig. 3 shows a second embodiment of a support section of an

equal layer in cross section,

Fig. 4 shows a second embodiment of a honeycomb body arrangement in

Cross section and

&iacgr;&ogr; Fig. 5 shows a third embodiment of a honeycomb body arrangement in

Cross-section.

In Fig. 1, a honeycomb arrangement according to the invention is shown in cross section. The honeycomb arrangement has a housing 8

is a honeycomb body 1 with a plurality of channels 5. The channels 5 extend in the axial direction of the honeycomb body 1. Each channel 5 is delimited by partition walls 6, 7. In the illustrated embodiment, the partition walls 6, 7 run in parallel or perpendicular planes, whereby the honeycomb body 1 has different stiffnesses in the radial direction R over its circumference U. Arrows indicate the directions of the honeycomb body 1 in which it has the highest radial strength.

The honeycomb body 1 is surrounded by a compensating layer 2. The compensating layer 2, which in the illustrated embodiment is in the form of a ceramic fiber mat, rests against the inner wall 9 of the housing 8.

The leveling layer 2 has supporting sections 3 which have a higher strength in the radial direction R than the other sections 4 of the

equal layer 2. The support sections 3 are arranged in areas of higher radial strength of the honeycomb body 1. In the embodiment shown, two support sections 3 are arranged diametrically opposite each other. The arrangement of the support sections 3 depends on the strength distribution of the honeycomb body 1. Thus, in particular in the case of channels or channel arrangements with a hexagonal cross section (not shown), it is advantageous to provide six support sections 3 spaced apart from one another in the circumferential direction U by 60° at the points at which the honeycomb body 1

&iacgr;&ogr; has its highest radial strength.

The forces directed radially inwards from the housing 8 are introduced into the honeycomb body 1 essentially via the support sections 3 of the compensation layer 2. The support sections 3 extend at least partially in the axial direction of the honeycomb body 1. The support sections 3 preferably extend over the entire axial length of the honeycomb body 1.

Fig. 2 shows a schematic design of a support section 3 of a compensating layer 2. The support section is formed by an insert 10. The insert 10 consists of a metallic material.

Fig. 3 shows a further embodiment of a support section 3 of a compensating layer 2, which is formed by three layers 11, 12, 13 of the compensating layer 2, which are folded onto one another.

Fig. 4 shows a second embodiment of a honeycomb body arrangement in cross section. The housing 8 in this embodiment has support segments 16 directed radially inwards in the circumferential direction U of the honeycomb body 1. The support segments 16 are in areas of increased radial strength of the

honeycomb body 1. The forces directed radially inwards from the housing 8 are essentially introduced via the support segments 16 and the support sections 3 thus created in the compensation layer 2 into areas in which the honeycomb body 1 has a higher radial strength, whereby damage to the honeycomb body 1 is avoided during installation in the housing 8 and during subsequent operation.

In the embodiments according to Fig. 1 and 4, it is necessary that a honeycomb body 1 is installed in a housing 8 with the correct relative position

&iacgr;&ogr; There are many ways to ensure this even in automated mass production. One particularly advantageous way is to provide the honeycomb body 1 with an optically and/or mechanically scannable positioning aid 18. However, this can be omitted in the case of non-circular cross-sections of the honeycomb body 1 and housing 8, for which the present invention is also suitable, since their relative position is determined by the cross-sectional shape, e.g. oval or ellipse.

In Fig. 5, another embodiment of a catalyst arrangement according to the invention is shown in cross section. In this embodiment, the honeycomb body 1 has radially outward-directed curvatures 17 in the peripheral areas of its highest radial strength, which create support sections 3 in the compensating layer 2. The curvatures 17 preferably form flat beads extending axially over the entire length of the honeycomb body 1, so that production by extrusion is possible.

The effect of the beads on the compensation layer 2 is the same as that of the support segments 16 in Fig. 4, except that the bulges 17 are always arranged in the correct position on the honeycomb body 1, whereas the support segments 16 must first be arranged in the correct position on the honeycomb body 1.

It is of course possible to produce supporting sections 3 in the "compensating layer 2" by taking simultaneous measures on the compensating layer 2 and/or the housing 8 and/or the honeycomb body 1. In particular, it can be provided that supporting sections 3 are produced alternately by taking measures on the housing 8, the honeycomb body 1 and/or the compensating layer 2.

The present invention is particularly suitable for the mass production of honeycomb body arrangements, such as those used in automobile construction for exhaust gas purification

&iacgr;&ogr; are required. In particular, thin-walled ceramic honeycomb bodies can be easily and durably installed in metal housings according to the invention. When using such honeycomb body arrangements as catalysts, the present invention also increases the thermal cycling capacity of the arrangements, which makes installation close to the engine easier. The invention is also suitable for honeycomb bodies that are used as carriers for other exhaust gas purification agents, such as hydrocarbon traps, NOx storage, water traps, etc.

Emitec Society for List of reference symbols: 20 U Support segment Emissions Technology Ltd. Catalyst carrier body R Curvature Leveling layer Positioning aid 5
1 Support section 2 other peripheral areas Scope 3 channel Radial direction 4 partition wall &iacgr;&ogr; 5 Housing 6, 7 Interior wall 8th inlay 9 is 11, 12, 13 layers of leveling layer 10 16 17 18

30 December 1997 E40539GBM KA/MB/czl

Claims (20)

Emitec Gesellschaft für --- 30. December 1997 Emissionstechnologie mbH E40539GBM KA/MB/czl Claims: 1. Honeycomb body arrangement with a metallic housing (8) in which a honeycomb body (1) with a plurality of channels (5) separated from one another by partition walls (6, 7) is arranged, which has different radial strengths over its circumference (U), and with a &iacgr;&ogr; at least in parts of the circumference (U) between the housing (8) and the honeycomb body (1), characterized in that the compensating layer (2) in the circumferential direction (U) of the honeycomb body (1) has at least two support sections (3) which exert higher forces on the honeycomb body in the radial direction (R) than outside the support sections (3) in the other circumferential areas (4), the support sections (3) being located in areas of higher radial strength of the honeycomb body (1). 2. Honeycomb body arrangement according to claim 1, characterized in that the honeycomb body is a ceramic, in particular extruded, honeycomb body with flat partition walls (7), the radial strength of which is higher in the direction of the partition walls (7) than in other directions. 3. Honeycomb body arrangement according to claim 1 or 2, characterized in that the support sections (3) have a higher weight per unit area than the other peripheral regions (4). 4. Honeycomb body arrangement according to claim 3, characterized in that the support sections (3) have a higher density than the other peripheral regions (4). 5. Honeycomb body arrangement according to claim 1, 2, 3 or 4, characterized in that the support sections (3) are at least partially formed by at least one insert (10). 6. Honeycomb body arrangement according to claim 5, characterized in that the insert (10) has a structure which gives the support section (3) a higher strength than the other sections (4). 7. Honeycomb body arrangement according to claim 5 or 6, characterized in that the insert (10) consists of a material which has a higher strength than a material of the other peripheral regions (4). 8. Honeycomb body arrangement according to claim 5, 6 or 7, characterized in that the insert (10) consists of a metallic material. 9. Honeycomb body arrangement according to one of claims 1 to 8, characterized in that the compensating layer (2) is at least partially mat-shaped. 10. Honeycomb body arrangement according to claim 9, characterized in that the compensating layer (2) is a mat made of ceramic fibers, in particular a swelling mat. 11. Honeycomb body arrangement according to claim 9 or 10, characterized in that the support sections (3) are formed by at least two, preferably three, layers (11, 12, 13) of the compensating layer (2). 12. Honeycomb body arrangement according to one of claims 1 to 11, characterized in that the housing (8) in the circumferential direction (U) of the Honeycomb body (1) has at least two radially inwardly directed support segments (16) for forming the support sections (3). 13. Honeycomb body arrangement according to one of claims 1 to 12, characterized in that with an even number of support sections (3) in a cross section, two support sections (3) are diametrically opposite one another. 14. Honeycomb body arrangement according to one of claims 1 to 13, characterized in that the honeycomb body (1) and/or the compensating layer (2) and/or the housing (8) have at least one positioning aid (18) for the correct relative positioning of the honeycomb body (1) and housing (8) or compensation layer (2). is 15. Honeycomb body arrangement according to claim 14, characterized in that the positioning aid is designed in the form of optical markings. 16. Honeycomb body arrangement according to claim 14 or 15, characterized in that the positioning aid is formed by at least one projection or one recess. 17. Honeycomb body arrangement according to one of claims 1 to 16, characterized in that the support sections (3) extend at least over part of the axial length of the honeycomb body (1). 18. Catalyst arrangement according to one of claims 1 to 17, characterized in that the honeycomb body (1) has on its side facing the compensating layer (2) at least two radially outwardly directed curvatures (17) for forming the support sections (3), wherein the curvatures (17) are formed in regions of higher radial strength of the honeycomb body (1). 19. Honeycomb body arrangement according to claim 18, characterized in that the curvatures (17) are designed as axially continuous beads. 20. Honeycomb body arrangement according to claim 18 or 19, characterized in that the curvatures (17) are produced by extruding the honeycomb body (1) by means of a correspondingly shaped extrusion tool &iacgr;&ogr; are.