DE9421332U1 - Device for the catalytic cleaning or decomposition of hot exhaust gases - Google Patents

Description

Device for catalytic cleaning or decomposition of hot exhaust gases

The invention relates to a device for the catalytic purification or decomposition of hot exhaust gases, in particular of an internal combustion engine, with a tubular housing arranged or attachable in the exhaust gas flow and at least two gas-permeable or gas-flowing catalyst bodies accommodated therein, axially spaced from one another, in particular those made of ceramic material, between whose mutually facing end faces a spacer ring is arranged.

A corresponding device is known, for example, from US-A 45 81 206. In the manufacture of this device, the catalyst bodies, which are covered on their outer circumference with a flexible casing, and the spacer ring are pushed axially into the housing, with a stamp-like tool on one

RALF ALBRECHT ■ 70372 STUTTGART (BAD CANNSjWTi)J SEELäEXijßTfVSsE'iJ/ie'-T'EJ.Ef6GJ07111 56 72 61 ■ TELEX 5 29 672 PATMF ■ TAX-No. DE 147 523

MANITZ ■ FINSTERWALD · HEYN -MORGAN -tlN^TEi^^LD · JftUL -£CHMfD.T · B9J38 MÖNCHEN ■ ROBERT-KOCH-STRASSE 1 · TELEPHONE (089) 22 42 11

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end of the housing serves as a stop and the parts to be inserted into the housing are pushed in and forwards one after the other from the other end of the housing by means of another punch.

The spacer ring consists of a rigid sheet metal part which is supported radially on the inner circumference of the housing, as well as ring parts made of flexible material arranged axially between the spacer ring and the facing end faces of the catalyst body, similar to the material of the flexible casing of the catalyst body.

This known design has poor thermal insulation in the area of the spacer ring, since the sheet metal part forms a heat-conducting bridge between the hot exhaust gases and the housing. Accordingly, the housing zone at the spacer ring is subjected to significantly greater thermal stress than the housing parts that encase the catalyst bodies.

Furthermore, the pressure pulsations of the exhaust gases have a destructive effect on the flexible rings between the sheet metal part and the facing end faces of the catalyst bodies, with the result that sooner or later the flexible casing of the catalyst bodies is also exposed to the destructive pulsations of the exhaust gases.

From DE-A 40 24 015 it is known to arrange a cylindrical ceramic ring axially between the catalyst bodies, which is covered on its outer circumference by an intumescent mat or the like, which radially supports the ceramic ring on

the inner wall of the housing. The catalyst bodies are held radially in the housing in basically the same way. The ceramic ring rests with its front edges tightly on the facing front sides of the catalyst bodies, so that the inflatable mats encasing the ceramic ring and the catalyst bodies are shielded from the pulsations of the exhaust gases. In addition, this known design ensures good thermal insulation of the housing from the hot exhaust gases, because the ceramic ring together with the inflatable mat encasing it offers relatively good thermal shielding. As a result, the housing is thermally loaded very evenly in the area of the catalyst bodies and the ceramic ring.

The arrangement of the ceramic ring and its production is comparatively expensive. This is especially true if the housing is not supposed to have a circular cross-section, but a cross-section that deviates from the circular shape, such as an ellipse or similar.

Therefore, the object of the invention is to demonstrate a new and inexpensive design which enables long service life and good thermal insulation in the area of the spacer ring.

This object is achieved according to the invention in that the spacer ring is designed as a torus-like hollow part made of sheet metal and has a resilient flexibility such that the end faces or edges of the spacer ring are able to fit tightly against the facing end faces of the catalyst bodies and

the spacer ring can adapt to the shape of the cross-section of the housing.

Due to its torus-like shape, the spacer ring forms a double-walled intermediate piece in the installed position when the front sides of the ring are in close contact with the facing front sides of the catalyst body, the inner wall of which is exposed to the exhaust gas and is separated from the outer wall by an air gap. This allows good thermal insulation of the housing, especially since insulating material, e.g. in the form of an expanded mat, can be arranged between the outer wall and the wall of the housing. As a sheet metal part, the spacer ring can also be designed with sufficient elasticity so that the spacer ring can easily fit against the facing front sides of the catalyst body and can also adapt to the shape of the cross section of the housing. Due to the elasticity, the different thermal expansions of the housing and the catalyst body are also compensated.

According to a particularly preferred embodiment of the invention, the spacer ring is composed of two annular shell parts which are arranged symmetrically to one another with respect to a radial center plane and have a U-profile with a frontal U-opening facing the other shell part.

The radially inner and/or radially outer U-legs of the two shell parts can be connected to each other by welding.

It is useful if the U-legs of the shell parts form radial ring webs on their free edges, which are directed radially outwards on the radially outer U-leg and radially inwards on the radially inner U-leg. This can ensure that the radially outer U-legs try to move radially outwards and the radially inner U-legs try to move radially inwards (widening the U-opening) when the spacer ring made up of the two shell parts is compressed in the axial direction.

Furthermore, it is expedient if the end faces of the spacer ring with a small radius of curvature merge into an essentially cylindrical inner peripheral wall of the spacer ring or into the radially inner U-legs of the shell parts, while the transition between the end faces of the ring and its outer peripheral wall or the radially outer U-legs of the shell parts has a comparatively large radius of curvature. This design ensures that the radially inner edge of the end faces of the spacer ring rests with particularly high pressure on the facing end faces of the catalyst bodies when the spacer ring is clamped between the catalyst bodies with axial pressure.

Furthermore, with regard to preferred features of the invention, reference is made to the claims and the following explanation of a particularly preferred embodiment, which is described with reference to the drawing.

This shows

Fig. 1 shows a schematic axial section of a housing with two catalyst bodies and a spacer ring arranged between them and

·· 6

Fig. 2 is an enlarged view of detail II in Fig. 1.

The device shown for the catalytic cleaning or decomposition of exhaust gases from an internal combustion engine has a housing 1, which is composed of a pipe part 2 with a circular or non-circular, in particular elliptical, cross-section and an inlet funnel 3 and an outlet funnel, the inlet funnel 3 being connected to an exhaust line (not shown) on the engine side and the outlet funnel 4 being connected to an exhaust line (not shown) leading to the atmosphere.

Inside the single-walled pipe part 2, two catalyst bodies 6 are arranged, each covered by an inflatable mat 5, between which a spacer ring 7, also covered by an inflatable mat, is arranged, so that a spacer 8 is created between the catalyst bodies 6, in which the exhaust gases initially passing through the catalyst body 6 on the left in Fig. 1 can mix before entering the catalyst body 6 on the right.

The catalyst bodies 6 as well as the spacer ring 7 and the associated inflatable mats 5 can be pushed axially into the pipe part 2 using stamp-like tools, where they are then held immovably by the inflatable mat 5 which swells under the heat of the exhaust gases.

The inflatable mat 5 should be shielded from pulsations of the exhaust gases, as these pulsations would destroy the inflatable mat 5 in the long term. For this reason, the catalyst bodies 6 are pushed against each other with sufficient axial pressure when inserted into the pipe part 2,

such that the spacer ring 7 rests sealingly on the facing end faces of the catalyst bodies 6.

On the opposite end faces of the catalyst bodies 6, the annular gaps between the inner wall of the tube part 2 and the peripheral side of the catalyst bodies are sealed by ring parts 9 made of steel wire mesh.

Inlet and outlet funnels 3,4 are each double-walled with outer parts 3' and 4 ¹ and inner parts 3" and 4", between which an air gap remains free for thermal insulation.

If necessary, heat-insulating material can also be arranged between the outer parts 3 ¹ or and the inner parts 3" or 4".

In the example shown, the outer parts 4 and 4' are welded to the pipe part 2, while the edges of the inner parts 3" and 4" facing the catalyst bodies 6 rest firmly on an area of the ring parts made of wire mesh that slightly overlaps the end faces of the catalyst bodies 6.

Furthermore, the inner parts 3" and 4" are connected to the respective outer parts 3' and 4' by welding at the inlet and outlet openings of the inlet funnel 3 and the outlet funnel 4.

In principle, it is also possible to connect the inner parts 3" and 4" to the pipe part 2 by welding. In this case, the inner parts 3" and 4" should have a ring joint in the area adjacent to the pipe part 2.

step which radially overlaps the facing front edges of the ring parts 9 made of wire mesh.

Particularly in this latter embodiment, the inner parts 3" and 4" can be held at the inlet and outlet openings of the inlet and outlet funnels 3 and 4 by means of a sliding fit within the outer parts 3' and 4".

As shown in particular in Fig. 2, the spacer ring 7 is designed as a torus-like sheet metal part, so that a heat-insulating air gap remains between the inner peripheral wall and the outer peripheral wall of the spacer ring 7.

The inner diameter of the spacer ring 7 is preferably only slightly smaller than the outer diameter of the catalytic converter body 6, so that their mutually facing end faces are only slightly overlapped by the spacer ring 7 and the entire cross section of the catalyst body 6 is largely available for exhaust gases flowing through.

The outer diameter of the spacer ring 7 is preferably significantly larger than the outer diameter of the catalyst body 6 in order to produce a relatively wide air gap between the inner peripheral wall and the outer peripheral wall of the spacer ring 7.

Accordingly, the inflatable mat 5 is significantly thinner in the area of the spacer ring 7 than in the area of the catalyst body 6.

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If necessary, the inflatable mat 5 can also be omitted in the area of the spacer ring 7. In this case, the spacer ring 7 can be supported radially directly on the inside of the pipe part, whereby small contact areas between the spacer ring 7 and the pipe part 2 can be achieved by forming an annular bead or radial projections on the outer peripheral side of the spacer ring 7 in order to limit heat transfer from the spacer ring 7 to the pipe part 2 as far as possible.

The inner peripheral wall of the spacer ring 7 merges with a very small radius of curvature into the end faces of the spacer ring 7 facing the catalyst bodies, while there is a transition with a comparatively large radius of curvature between the outer peripheral wall of the spacer ring 7 and the aforementioned end faces. This design ensures that the spacer ring 7 is more flexible in the area of its outer peripheral wall when subjected to axial compressive forces than in the area of its inner peripheral wall, so that the areas of the end faces of the spacer ring 7 that overlap the facing end faces of the catalyst bodies 6 can be clamped against the catalyst bodies 6 with particularly high pressure when the catalyst bodies 6 are pushed against one another with greater axial force during assembly in the pipe part 2. Due to the high surface pressure that can be achieved between the superimposed front ring zones of the catalyst body 6 and the spacer ring 7, a good seal can be achieved between the spacer ring 7 and the catalyst bodies 6.

In terms of production, it is advantageous if the spacer ring 7 consists of two annular

Shell parts are composed that are arranged symmetrically to a radial center plane of the spacer ring 7 and have a U-profile with U-openings facing each other. The edges of the U-legs facing each other are bent radially inwards in the U-legs forming the inner peripheral wall of the spacer ring 7 and radially outwards in the U-legs forming the outer peripheral wall of the spacer ring 7, so that in the transition area of the two shell parts or in the area of the radial center plane of the spacer ring 7 an outer and an inner annular bead or web is formed. This advantageously ensures that the radially outer legs try to move radially outwards and the radially inner legs try to move radially inwards as soon as the spacer ring 7 is subjected to pressure in the axial direction.

The shell parts forming the spacer ring 7 are welded together in a gas-tight manner at their radially outer legs and/or at their radially inner legs in order to keep pulsations of the exhaust gases away from the inflatable mat 5.

Claims (9)

&Bgr; 106 Claims: 1. Device for the catalytic purification or decomposition of hot exhaust gases, in particular of an internal combustion engine, with a tubular housing arranged or attachable in the exhaust gas flow and at least two catalyst bodies housed therein, axially spaced from one another, permeable to gas or through which gas flows, in particular those made of ceramic material, between whose mutually facing end faces a spacer ring is arranged, characterized, that the spacer ring (7) is designed as a torus-like hollow part made of sheet metal, which is axially and radially resilient. 2. Device according to claim 1,
characterized, that the outer circumference of the spacer ring (7) is larger than the outer circumference of the catalyst body (6). 3. Device according to claim 1 or 2, characterized in that the front sides of the spacer ring (7) merge with a small radius of curvature into an inner peripheral wall and with a large radius of curvature into an outer peripheral wall of the spacer ring (7). 4. Device according to one of claims 1 to 3, characterized in · that the spacer ring (7) is composed of two ring-shaped, axially adjacent shell parts which are arranged on both sides of a central radial plane of the spacer ring (7) and have a U-profile with a U-opening facing the other shell part. 5. Device according to one of claims 1 to 4, characterized in that on the outer peripheral wall of the spacer ring (7) there is arranged an annular bead or the like that projects radially outwards and/or on the inner peripheral wall of the spacer ring (7) there is arranged an annular bead that projects radially inwards. 6. Device according to claim 4 and 5, characterized in that the annular bead is formed by edges of the U-legs of the shell parts which are bent radially outwards or radially inwards. 7. Device according to one of claims 1 to 6, characterized in that an inflatable mat (5) is arranged radially between the outer circumference of the catalyst body (7) and the inside of the housing (2). 8. Device according to one of claims 1 to 7, characterized in that an inflation mat (5) is arranged radially between the spacer ring (7) and the inside of the tubular housing (2). 9. Device according to one of claims 1 to 7, characterized in that the spacer ring (7) is radially supported directly on the inside of the tubular housing (2).