DE4017832A1 - Ceramic spacer ring with shaped support faces - in contact with end faces of honeycomb bodies of exhaust catalyst - Google Patents

Abstract

A ceramic ring (31) for spacing the catalytic honeycomb bodies (10,20) of an exhaust gas catalyst, has an outside diameter greater than the honeycomb body diameter and has shaped support faces (41) in contact with the end faces (11,21) of the honeycomb bodies (10,20). Pref. the support faces (41) consist of a material (pref. polyethylene or polypropylene) which combusts at the operating temp. ADVANTAGE - The ring covers little or none of the active honeycomb body surface.

Description

The invention relates to a ceramic ring for adjustment a defined distance between the catalytic Honeycomb bodies of an exhaust gas catalytic converter.

From US-PS 37 54 870 and DE-OS 36 26 728 and 36 26 729 are catalytic converters for motor vehicles known in a metal case at least two have catalytically coated, ceramic honeycomb bodies. There is a ceramic ring between adjacent honeycomb bodies used. This ceramic ring has essentially two Tasks: During assembly, he ensures the exact mutual distance of the honeycomb body, which in turn Precondition is for an exact positioning of the Honeycomb body in the housing; he also supports that Insulating material on the inside of the housing. During the It protects the insulating material from the hot and hot during operation pulsating exhaust gases.

The main advantage of using one Ceramic spacer ring instead of the one previously used Metal spacer rings exist in the practical too neglecting thermal expansion of ceramics. It doesn't have to an expansion gap still adhered to a sliding seat be provided.

The disadvantage, however, is that the end faces of the ceramic ring a not inconsiderable area of the honeycomb body cover up so that it is no longer for the exhaust gas flow is available. With a diameter of the honeycomb body of, for example, 100 mm and a ring thickness of for example, 6 mm go 23% of the way Honeycomb body area lost. Even if the strength of the Ceramic ring on the face to, for example, 3 mm  is reduced, as in DE-OS 36 26 728 and 36 26 729 is shown, the inactive The area of the honeycomb body is still 12%. Thereby the exhaust gas flow concentrates on the center of the Honeycomb body. These are therefore thermally high and above all unevenly loaded and therefore more prone to breakage. The length of the honeycomb body must also be increased to To guarantee catalytic cleaning.

The present invention is based on the object To specify ceramic spacer ring of the type mentioned at the outset, relatively little, preferably almost, when used no active honeycomb body surface is covered.

This problem is solved by a generic Ceramic ring with the characteristics according to the characteristics of the Claim 1.

In the solution according to the invention, the essential part of the ring is outside the honeycomb end faces. These are only covered by the separate support surfaces ( 41 ... 45 ), preferably three. The invention makes use of the knowledge that precisely because of the use of ceramic, no compressive stresses arise at the operating temperature.

The production of such a ring is as simple as with the conventional ceramic spacer rings.

According to a first development of the invention End faces chamfered inwards, preferably by 45 Degrees, with the support lugs in the area of End surface bevel are formed.

Thanks to the bevelled end faces, the  Ceramic body and the ceramic ring during the assembly of itself. So you can be sure that honeycomb bodies, Ceramic ring and the insulation wrapped around it Catalytic converter housing are correct without this should be checked, which in practice anyway only is difficult possible.

Thanks to the bevel of the end faces touch Ceramic ring and honeycomb body only on their circumference. The angle of around 45 degrees represents a good compromise between the ability to center on the one hand, which with increasing Angle is improved, and stability versus Damage to the edge of the honeycomb body with decreasing angle increases.

The support lugs on the ceramic ring close some of the Honeycomb openings; nevertheless approximately 99% of the Honeycomb front face open. So the loss of area is hardly noticeable.

An advantageous development of the invention Basic idea can be achieved in that the Inner diameter of the ceramic ring is the outer diameter of the Honeycomb body. In this variant, the The honeycomb end face is also free when the end faces of the ceramic ring are not beveled. This results in the decisive advantage that these rings by cutting from an extruded ceramic strand in large Quantities can be manufactured inexpensively while all previously known ceramic spacer rings with reduced Surface coverage due to its complicated shape only in Mold casting processes could be produced.

The support surfaces can be different Generate species.  

According to a first variant, the support surfaces are through cylindrical formations formed on the inner ring wall.

According to a second variant, the support surfaces are through radially inwardly curved areas of the ring wall are formed.

According to a third variant, the support surfaces are through at least one approximately concentric inner ring and this (n) with the outer ring connecting spokes formed. It is it is possible to place the inner ring in the thermally highly stressed Center of the honeycomb body to be laid, causing the exhaust gas flow is forced to increase by the outer honeycomb areas flow.

According to a fourth variant, the support surfaces are through wide-meshed honeycomb walls formed. Here is the Spacer ring also from a piece of honeycomb body; while the catalytically active honeycomb body with approx. 400 cells per Square inches are suitable as a spacer ring Honeycomb body with less than 10 honeycomb cells per square inch.

They are preferably exposed to the exhaust gas flow Surfaces of the ceramic spacer ring are also catalytic coated. In this case, the Designs of the spacer ring as a honeycomb body or as concentric rings as these have relatively large surfaces have. Through this development of the invention Aim to use the same catalytic cleaning with shorter Achieve building units, effectively supported.

The minimal loss of area through the support surfaces can be avoid completely if this comes from a Operating temperature burning material, for example Polyethylene or polypropylene. During assembly  the plastic support surfaces hold the neighboring ones Honeycomb body at a precise distance without it becoming a Damage to the honeycomb body can occur. After this Closing the catalytic converter housing guarantees this exact positioning of the honeycomb body and the ceramic ring, so that the plastic support surfaces are then unnecessary.

Based on the drawing, the invention in the form of a Embodiment will be explained in more detail. Show it

Fig. 1 in part a longitudinal section through a combination of two catalytically active honeycomb bodies and a first ceramic spacer ring,

Fig. 2 is a perspective view of a second ceramic spacer ring,

Fig. 3 is a perspective view of a third ceramic spacer ring,

Fig. 4 is a perspective view of a fourth ceramic spacer ring,

Fig. 5 is a perspective view of a fifth ceramic spacer and

Fig. 6 is a perspective view of a combination of two catalytically active honeycomb bodies and the second ceramic spacer ring.

Fig. 1 shows a longitudinal section through a ceramic ring 31 with an outer diameter D and inner diameters d which during assembly, the two catalytically active ceramic honeycomb body 10, stops 20 with an outside diameter H at the desired distance. The end faces 41 of the ceramic ring 31 are chamfered inward at an angle of approximately 45 degrees, so that the honeycomb bodies 10, 20 and the ceramic ring 31 only touch along the peripheral edge of the honeycomb bodies 10, 20 . The full cross section of the honeycomb bodies 10, 20 is thus available for exhaust gas purification.

In order to reduce the compressive forces on the peripheral edge of the honeycomb bodies 10, 20 during assembly, support lugs 51 are formed on the end faces 41 of the ceramic ring 31 . If the support lugs 51 are made from a plastic material that burns at operating temperature, they fully fulfill their support purpose during assembly, but during operation they release the full end face 11, 21 of the honeycomb body 10, 20 for exhaust gas routing.

Fig. 2 shows in perspective a second ceramic spacer ring 32. Its inside diameter corresponds to the outside diameter of the honeycomb body (see Fig. 6). Semi-cylindrical projections 52 are provided on the inner surface of the ceramic ring 32, whose end faces abut against the end faces of the honeycomb body. The actual end face 40 of the spacer ring 32 thus lies outside the active honeycomb body end face.

Fig. 3 shows a perspective view of a third ceramic spacer ring 33. Here the support surfaces are formed in that areas 53 of the ring wall are curved radially inwards. The main area of the end face 40 of the ring 33 is again outside the end faces of the honeycomb body.

Fig. 4 shows in perspective a fourth ceramic spacer ring 34. An inner ring 54 is provided concentrically to the outer region of the ring 34 with the end face 40 , which is connected to the outer ring via radial spokes 54 ' . The inner ring 54 and the spokes 54 ' form the support surfaces. By extending the spokes 54 ' , the inner ring 54 can be brought into the thermally highly stressed central zone of the honeycomb body. As a result, the exhaust gas flow is forced to flow more through the outer surface areas of the honeycomb bodies which are not subject to much thermal stress.

Fig. 5 shows in perspective a fifth ceramic spacer ring 35. This is designed as a honeycomb body with honeycomb walls 55 . However, the honeycombs themselves are considerably wider-meshed than those of the catalytically active monoliths. While the catalytically active honeycomb bodies are produced with a honeycomb number of approx. 400 per square inch, 35 honeycomb bodies with less than 10 honeycomb cells per square inch are suitable as ceramic spacer rings.

Fig. 6 shows in perspective view an assembly of two catalytically active honeycomb bodies 10, 20 using the third ceramic spacer ring 33. It can be seen how little of the catalytically active end face of the honeycomb body is covered by the radially inwardly curved regions 53 of the ring wall.

The ceramic spacer rings shown in FIGS. 2 to 6 have the common advantage that they can be produced by cutting off an extruded ceramic strand without any finishing of the end faces.

The ceramic spacer rings shown in FIGS . 1, 2 and 4, to a certain extent also in FIG. 5, have in common that the support surfaces and support lugs can be attached in a separate operation from a plastic, such as polyethylene or polypropylene, which burns at operating temperature. These plastic spacer elements ensure that the catalytically active honeycomb bodies are kept exactly at a mutual distance during assembly. After closing the catalyst housing, the honeycomb body and spacer ring are held by it; thanks to the use of ceramics, there are no longer any compressive stresses during operation, so that the spacer elements are unnecessary. These burn when they are started up for the first time, so that the full honeycomb cross section is then available for the catalytic purification of the exhaust gases.

Claims (11)

1. Ceramic ring ( 31, 32, 33, 34, 36 ) for setting a defined distance between the catalytic honeycomb bodies ( 10, 20 ) of an exhaust gas catalytic converter, characterized in that at least its outer diameter (D) is larger than the diameter (H ) the honeycomb body ( 10, 20 ) and that support surfaces ( 41, 42, 43, 44, 45 ) are formed, which have contact with the end faces ( 11, 21 ) of the honeycomb body ( 10, 20 ). 2. Ceramic ring according to claim 1, characterized in that the end faces ( 41 ) are chamfered inwards, preferably by 45 degrees. 3. Ceramic ring according to claim 2, characterized in that support lugs ( 51 ) are formed in the region of the end surface bevel. 4. Ceramic ring according to claim 1, characterized in that its inner diameter (d) corresponds to the diameter (H) of the honeycomb body ( 10, 20 ). 5. Ceramic ring according to claim 1 or 4, characterized in that the support surfaces are formed by cylindrical projections ( 52 ) on the ring inner wall. 6. Ceramic ring according to claim 1 or 4, characterized in that the support surfaces are formed by radial, inwardly curved areas ( 53 ) of the ring wall. 7. Ceramic ring according to claim 1 or 4, characterized in that the supporting surfaces are formed by at least one approximately concentric inner ring ( 54 ) and this (s) with the outer ring ( 34 ) connecting spokes ( 54 ' ). 8. Ceramic ring according to claim 1 or 4, characterized in that the support surfaces are formed by wide-mesh honeycomb walls ( 55 ). 9. Ceramic ring according to claim 8, characterized in that he as a honeycomb body with less than 10 honeycomb cells per Square inch is formed. 10. Ceramic ring according to claim 7, 8 or 9, characterized characterized in that its exposed to the exhaust gas flow Surfaces are coated catalytically. 11. Ceramic ring according to one of claims 1 to 10, characterized in that the supporting surfaces ( 41 ... 45 ) consist of a material which burns at the operating temperature, preferably polyethylene or polypropylene.