EP0471175A1 - Process for manufacturing a device for the catalytic purification or decomposition of hot waste gases - Google Patents

Abstract

The casing (1) comprises at least two tubular casing sections (4, 5) inserted axially one into the other, into which the catalyst bodies (8) can be inserted axially together with a jacket formed by expanded mats, the set position being predetermined by stops (7). <IMAGE>

Description

The invention relates to a device for the catalytic purification or decomposition of hot exhaust gases, in particular an internal combustion engine, with a tube-like housing arranged or attachable in the exhaust gas flow and at least one catalytically active body (catalyst body) accommodated therein or coated with catalytically active material, which is held in the housing by means of a resilient mat encasing the body in an annular manner, which is formed at least within an area encircling the associated catalyst body in the form of an expandable mat consisting of a material which irreversibly swells under heat and which seals an annular spacing zone between the catalyst body and the wall of the housing, which is constructed from at least two axially assembled tube-like housing sections.

Internal combustion engines of motor vehicles are today equipped to a large extent with devices for catalytic cleaning or decomposition of the exhaust gases in order to significantly reduce the proportion of particularly harmful or toxic exhaust gases. The catalyst body generally consists of ceramic material, the body being penetrated by a large number of narrow channels, the walls of which are coated with catalytically active material, as a rule platinum. If necessary, however, the catalyst body can also consist of metal. In any case, each catalyst body forms a monolith, which is resiliently held in the housing.

DE-OS 38 11 224 describes a device of the type mentioned at the beginning with a catalyst body designed as a metal monolith. The metal monolith has a monolith jacket, for example made of sheet steel, the end edges of which protrude beyond the end faces of the metal monolith. These end edges are welded to funnel-shaped connecting parts, which are arranged together with the monolith jacket within a housing which encloses the monolith jacket and the connection funnels at a radial distance, the spacing space or the like being provided by an expansion mat. is filled out. In order to ensure that no undesirable tension occurs between the monolith jacket and the housing during operation due to the hot exhaust gases flowing through the catalyst body, it is provided that the housing consists of two axially assembled housing sections which are connected to one another via a sliding seat and are accordingly able to move against one another .

In addition, DE-OS 38 11 224 also describes a modified embodiment in which the monolith jacket is connected to at least one connecting funnel via a sliding seat and the housing has an integral design. DE-OS 38 11 224 does not explain in more detail how the illustrated embodiments are to be produced. However, in the drawing (Fig. 7) a housing cross section is shown, from which it can be seen that the housing or the housing parts each consist of two interconnected shell parts into which the metal monolith together with the inflatable mat enveloping it and the connection funnels, etc. can be inserted before connecting the shell parts.

From DE-OS 25 25 661 a further device is provided for catalytic cleaning or decomposition of hot exhaust gases is known, in which the catalyst body is resiliently held within a housing by means of a metal structure arranged between the housing inner wall and the catalyst body. In order to avoid that exhaust gases can bypass the catalyst body through the annular space filled with knitted metal, ring flanges or the like are inside the housing. arranged, which radially overlap the cross section of the metal knitted fabric and an adjacent ring zone on the end faces of the catalyst body and thus shield against the exhaust gas flow. In addition, the like axially between the ring flanges. and said ring zones on the end faces of the catalyst body each have a flexible sealing ring, for example in the form of a gas-filled ring hose.

Information about how the catalyst body is housed in the housing during the manufacture of the device is not given in DE-OS 25 25 661.

DE-PS 38 30 352 shows a further device for the catalytic cleaning or decomposition of hot exhaust gases. Here are the catalyst body and funnel-shaped housing linings adjoining it on the end face within a housing with the interposition of an inflatable mat or the like. arranged. Spacer rings or the like are located axially between the funnel-shaped inner linings mentioned and the facing end faces of the catalyst body. arranged, which consist of a material that burns away under heat, so that the like when commissioning the device in the area of the mentioned spacer rings or the like. a space is created between the catalyst body and the funnel-shaped inner linings by the hot exhaust gases. Tensions between the catalyst body and the above-mentioned lining parts can thus be avoided.

Incidentally, more precise information is also missing here about how the device shown could be made.

The object of the invention is now to provide a device of the type specified at the outset that is easy to manufacture and is characterized by a particularly reproducible arrangement of the catalyst body or the catalyst bodies.

This object is achieved in that stops are arranged in the housing on the end faces of the catalyst body or on the foremost and rearmost end faces of the successive catalyst bodies in the flow direction of the exhaust gas, which radially overlap the end faces mentioned, that the catalyst body or bodies with the associated one Mat are inserted axially into the housing sections and the housing sections are firmly connected to one another with compensation for manufacturing tolerances in an axially assembled state, in which the stops abut the assigned end faces of the catalyst body or the catalyst bodies and the optionally successive catalyst bodies against one another or against them arranged spacers are pushed, and that by axially between the stops and the facing end faces of the catalyst body or the catalyst body and inserted under heat spacing elements which burn off or dissolve, a predeterminable axial spacing space can be formed or formed.

In the construction according to the invention, therefore, each catalyst body with the associated mat can be pushed into the associated housing section or the corresponding housing sections in the manner of a plug. A visual inspection is easily possible here.

A particular advantage of the invention is that the axial position of the catalyst body or the catalyst body in the housing is precisely predetermined by the stops arranged therein. After inserting the catalyst body or the catalyst body into the respective housing section or the housing sections, the same are plugged together with sufficient force that the stops come to rest on the assigned end faces of the catalyst body or the catalyst body and in any case an exact adaptation of the housing to the dimensions of the catalyst body or the catalyst body is reached.

At the same time, the spacer elements which burn off or dissolve under the action of heat ensure that, after the housing has been installed between the stops and the facing end faces of the catalyst body or the catalyst body, a precisely defined free space can be generated, which prevents the stops and the respective catalyst body from being prevented destructive compressive forces can be effective, for example if the housing and the catalyst body or bodies expand to the same extent under the influence of heat or shrink to the same extent when cooled. Said axial distance between the stops and the respectively adjacent catalyst body is completely harmless for its seat in the axial direction of the housing, because when the device is first subjected to heat, the inflatable mat, which holds the catalyst body or the catalyst bodies in the housing, swells and thus the catalyst body or fixes the catalyst body immovably.

In addition, it is advantageous that the housing sections can in principle be produced in any manner. In addition to producing the housing sections from pipe sections, production from shell parts is also possible, which can be connected to one another to form the pipe-like housing sections before the respective catalyst body is inserted.

In general, the production of the housing sections from pipe sections is advantageous if the housing has a circular or slightly eccentric cross section. In the case of markedly non-circular cross sections, in particular if the cross sections have height and width dimensions which differ greatly from one another, it is generally advisable to produce the housing sections from shell parts.

Otherwise, with regard to preferred features of the invention, reference is made to the claims and the following explanation of particularly advantageous embodiments, which are shown in the drawing.

• Fig. 1 einen Längsschnitt einer ersten Ausführungsform der erfindungsgemäßen Vorrichtung zur katalytischen Reinigung bzw. Zerlegung von heißen Abgasen, wobei das Gehäuse aus Rohrabschnitten zusammengesetzt ist, die mit trichterartigen doppelwandigen Anschlußstücken verschweißt sind, und
• Fig. 2 einen der Fig. 1 entsprechenden Längsschnitt einer abgewandelten Ausführungsform, bei der die Gehäuseabschnitte aus Schalenteilen bestehen.

It shows

• Fig. 1 shows a longitudinal section of a first embodiment of the device according to the invention for the catalytic cleaning or decomposition of hot exhaust gases, the housing being composed of pipe sections which are welded to funnel-like double-walled connecting pieces, and
• Fig. 2 is a longitudinal section corresponding to FIG. 1 of a modified embodiment in which the housing sections consist of shell parts.

The device shown in Fig. 1 for the catalytic cleaning and decomposition of combustion gases of a vehicle engine has a housing 1, which between an engine-side exhaust pipe 2 and one to the outside to the atmosphere re or to an exhaust silencer leading exhaust-side exhaust pipe 3 is arranged.

The main part of the housing 1 is formed by two pipe sections 4 and 5. The pipe section 5 has a widened left end in the manner shown, such that the pipe section 4 can be inserted into this end. The two pipe sections 4 and 5 are welded to one another at a peripheral seam 6.

At the ends of the pipe sections 4 and 5 facing away from each other, an inwardly projecting ring step with a radial ring surface 7 is formed.

Within the main part of the housing 1 formed by the pipe sections 4 and 5, two catalyst bodies 8 are arranged at a distance from one another. In a manner known per se, these are ceramic monoliths which are penetrated by a large number of narrow channels in the axial direction of the housing 1. The walls of these channels are covered with catalytically active material, usually platinum, in order to be able to catalytically break down the exhaust gases passing through the catalyst bodies 8 and thus detoxify them.

The catalyst bodies 8 are each covered by an inflatable mat 9, which consists of an irreversibly swellable material under the influence of heat and also acts in the manner of thermal insulation, so that the catalyst body 8 heated by the hot exhaust gases flowing through it only comparatively little heat to the outside of the pipe sections 4 and 5 transferred.

Between the mutually facing end faces of the catalyst bodies 8, a ceramic ring 10 is arranged as a spacer, which is coated in a manner similar to the catalyst bodies 8 by an inflatable mat 11 and is held within the pipe sections 4 and 5.

The end face of the ceramic ring 10 is practically gap-free on the facing end faces of the catalyst body 8, so that the expansion mats 9 and 11 of the catalyst body 8 and the ceramic ring 10 between the catalyst bodies 8 are practically not acted upon by the exhaust gases flowing through the housing 1 and their pulsations can. This is important because the material of the inflation mats 9 and 11 can only withstand the pulsations of the exhaust gases for a limited time.

On the facing ends of the catalyst body 8 or on the annular surfaces 7 of the pipe sections 4 and 5, the catalyst bodies 8 enclosing sealing rings 12 made of wire mesh are arranged, which prevent the pulsations of the exhaust gases by the annular gaps between the annular surfaces 7 and the facing End faces of the catalyst body 8 remain, which can inflate the inflatable mats 9 of the catalyst body 8 in a destructive manner.

The annular gaps mentioned between the annular surfaces 7 and the catalyst bodies 8 must be present because the housing 1 or the pipe sections 4 and 5 expand to different extents under the influence of the hot exhaust gases or shrink at different speeds when cooled. For example, without the annular gaps, destructive compressive forces could occur between the annular surfaces 7 overlapping the facing end faces of the catalyst bodies 8 and the ceramic bodies 8 if the pipe sections 4 and 5 previously heated by the exhaust gases are suddenly and strongly cooled by spray water (for example in a car washer for vehicles) and shrink accordingly.

Adequate dimensioning of the annular gaps mentioned is ensured in the assembly of the catalyst bodies 8 in the pipe pieces 4 and 5 explained below by annular disk-shaped inserts 13 made of, for example, ceramic paper material, which burns or dissolves quickly under the action of the hot exhaust gases.

At the opposite ends of the tube pieces 4 and 5 funnel-like double-walled connecting pieces 14 and 15 are arranged, wherein the space between the inner and outer wall can be filled with heat-resistant heat insulation material 16, for example a ceramic-based material. A desirable noise insulation is achieved at the same time by this filling material.

On the inner walls 14 'and 15' of the connecting pieces 14 and 15 are formed on the ends adjacent to the pipe pieces 4 and 5 in each case radially outwardly directed annular surfaces in the manner of ring flanges, which on the facing sides of the annular surfaces 7 forming the annular steps of the tubular pieces 4 and 5 rest and are welded on their outer circumferences together with the outer walls of the connecting pieces 14 and 15 along the circumferential seams 17 and 18 to the pipe pieces 4 and 5, respectively.

At the ends of the connecting pieces 14 and 15 facing away from one another, the inner walls 14 'and 15' have tubular end regions which, with the formation of a sliding seat, that is to say axially displaceably, protrude into an axial annular gap which extends between the outer circumference of the exhaust pipe 2 or 3 and the Outside wall of the connector 14 or 15 is formed. To form these annular gaps, the outer walls of the attachment pieces 14 and 15 each have tubular end regions with ring steps 19, the radial height of which is adapted to the thickness of the inner walls 14 'and 15'. The end edges of the tubular end pieces of the outer walls of the connecting pieces 14 and 15 are along the peripheral seams 20 and 21 welded to the exhaust pipes 2 and 3.

In the manufacture of the device shown in FIG. 1, the catalyst bodies 8 are first arranged in the associated pipe sections 4 and 5, which are still separated from one another. First, the annular disk-shaped inserts 13 are inserted, in each case from the ends of the pipe sections 4 and 5 remote from the annular surfaces 7. Then the associated catalyst body 8, which was previously covered with the associated inflatable mat 9 and provided at one end with the associated wire mesh sealing ring 12, is inserted axially into the associated pipe section 4 or 5 in the direction of the annular surface 7.

The ceramic ring 10, which was also previously covered with the associated inflatable mat 11, is now inserted into one of the pipe sections 4 and 5. Now the pipe sections 4 and 5 can be axially one into the other or. are plugged onto one another, with sufficient axial thrust forces ensuring that the catalyst bodies 8 rest against the annular disk-shaped inserts 13 and the ceramic ring 10 without play. At the same time, the pipe sections 4 and 5 are welded along the circumferential seam 6.

The welding of the pipe sections 4 and 5 to one another along the circumferential seam 6 can take place simultaneously with the welding of the pipe sections 4 and 5 to the associated connecting pieces 14 and 15 along the circumferential seams 17 and 18, if the connecting pieces 14 and 15 have been prepared accordingly beforehand.

For this purpose, essentially only the outer wall and the inner wall of the connecting pieces 14 and 15 have to be plugged into one another with the interposition of the heat insulation material 16. Then the connecting pieces 14 and 15 are pushed axially against the pipe pieces 4 and 5 with sufficient thrust force in order to be able to simultaneously weld the inner and outer walls of the connecting pieces 14 and 15 to the facing ends of the pipe pieces 4 and 5 along the peripheral seams 20 and 21.

As soon as hot exhaust gases are passed through the device shown for the first time, the ring-shaped inserts 13 burn off or dissolve, at the same time the material of the inflation mats 9 and 11 swells, so that on the one hand between the annular surfaces 7 of the pipe sections 4 and 5 and the facing end faces of the Catalyst body 8 annular gaps are formed with a predetermined width by the inserts 13 and on the other hand, the catalyst body 8 and the ceramic ring 10 are held axially fixed in the pipe sections 4 and 5.

In the production shown, the axial dimensions of the main part of the housing 1 formed by the pipe pieces 4 and 5 are exactly adapted to the dimensions of the catalyst body 8 and the ceramic ring 10, i.e. all manufacturing tolerances are compensated.

The embodiment shown in FIG. 2 differs from the embodiment according to FIG. 1 first in that the housing 1 is composed of two housing halves 22 and 23, each of which has a section encasing the associated catalyst body 8 with a constant cross section and a funnel-shaped widening section have, which corresponds to the connecting pieces 14 and 15 in Fig. 1.

In this type of construction, the housing halves 22 and 23 are expediently each constructed from shell parts which are tightly connected or welded to one another at longitudinal seams which are not visible in FIG. 2.

In this embodiment, the inner walls 14 'and 15' of the connection areas can be inserted into the housing halves 22 and 23 together with the associated heat insulation material 16 from the ends of the housing halves 22 and 23 which are larger in cross section.

According to a first embodiment, which is shown in FIG. 2 for the inner wall 14 ', an annular bead 24 projecting radially inwards can be formed on the end of the inner wall 14' which has the larger cross section and which extends into a radially outwardly projecting flange-like annular surface 25 continues, wherein in the transition area between the annular bead 24 and the funnel-shaped part of the inner wall 14 'an annular bead 26 is formed with its convex side projecting outwards. Between this ring bead 26 and the wall of the housing half 22 spaced therefrom, a sealing ring 27 made of wire mesh is clamped, which is arranged together with a further sealing ring 28 made of wire mesh in a bead of this housing half 22 running in the circumferential direction of the housing half 22, the ring surface 25 of the inner wall 14 'protrudes into the gap between the sealing rings 27 and 28. This ensures the axial position of the end of the inner wall 14 ′ facing the catalyst body 8.

After arranging the inner wall 14 'in the housing half 22 and after installing the latter sealing ring 28, the catalyst body 8 enclosed by the housing half 22 can be arranged in the housing half 22. In order to prevent direct contact between the right end region of the inner wall 14 'in FIG. 2 and the facing end face of the catalyst body 8, annular disk-shaped inserts 29 are placed on the flank of the annular bead 24 facing the catalyst body 8, which inserts 29 in FIG 1 correspond. Then the catalyst body 8, which previously with the associated inflatable mat 9 was encased, inserted axially into the housing half 22.

According to a modified embodiment, the sealing rings 27 and 28 can also be combined into a single wide sealing ring 30, as is shown in the case of the inner wall 15 'within the housing half 23. The sealing ring 30 forms a press and slide fit for the associated end of the inner wall 15 ', while the other end of the inner wall 15' is fixedly connected or welded to the housing half 23 for axial securing of the position.

Between the right end face of the right catalyst body 8 in FIG. 2 and the facing end face of the inner wall 15 ', inserts 29 are again arranged from a material that burns or dissolves under the influence of heat, so that during later operation, i.e. during exhaust gas separation or purification, a sufficient distance remains between the catalytic converter body 8 and the inner wall 15 'and no axial pressure forces can be transmitted. The inserts 29 are secured in their position on the side facing the inner wall 15 'by the flank of the inner annular bead 24 formed on the inner wall 15' facing the catalyst body 8 or by an edge region 31 which is turned radially inward.

After arranging the inner wall 15 ', the catalyst body 8 assigned to the housing half 23 can be inserted axially into the housing half 23 with its inflatable mat 9.

As soon as the housing halves 22 and 23 with the inner walls 14 'and 15' and the catalyst bodies 8 have been installed, the ceramic ring 10 with its inflatable mat 11 encasing it is pushed axially into one of the housing halves 22 and 23, respectively, after which the housing halves 22 and 23 axially plugged together, with sufficient axial thrust force, such that the ends of the ceramic ring 10 lie against the facing ends of the catalyst bodies 8 without gaps and the ends of the catalyst bodies 8 facing away from one another with the annular inserts 29 being clamped against the facing ends of the inner walls 14 ' and 15 'are pushed. The housing halves 22 and 23 are then welded to one another along the peripheral seam 6.

Optionally, the embodiment shown in Fig. 2 can also be modified in such a way that the inflatable mat 9 of each catalyst body 8 projects into the space between the inner walls 14 'and 15' and the housing halves 22 and 23 or fills this space. Such an arrangement is similar to the embodiment shown in the right part of FIG. 2, only the sealing ring 30 is omitted. In addition, the annular gap between the inner wall 15 'and the catalyst body 8 is expediently provided by a heat-resistant woven or wire mesh layer to protect the inflatable mat 9 sealed against the pressure pulsations of the exhaust gases, the fabric or wire mesh layer mentioned encasing adjacent areas of the catalytic converter body 8 and the inner wall 15 'from the outside.

In this embodiment, the catalyst body 8 and the associated inner wall 15 '(or 14') can be pushed together axially into the housing half 23 (or 22) after being coated with the inflatable mat 8, the axial distance between the inner wall 15 '(or 14' ) and the adjacent catalyst body 8 is in turn secured by the previously arranged annular inserts 29.

In the embodiments shown in FIGS. 1 and 2, it was assumed that the pipe section 5 and the housing half 23 are slightly widened at their end facing the pipe section 4 and the housing half 22 such that the facing end of the pipe section 4 or the housing half 22 can be inserted into the expanded area.

Instead, it is also possible to design the mutually facing ends of the pipe sections 4 and 5 or the housing halves 22 and 23 with the same cross-section and a joint remaining between the pipe sections 3 and 4 or the housing halves 22 and 23 by a casing that surrounds the housing 1 on the outside To complete sheet metal strips, which is welded at peripheral seams to the pipe sections 3 and 4 or the housing halves 22 and 23.

In addition, both the pipe sections 4 and 5 and the housing halves 22 and 23 can be dimensioned with a greater axial length such that two catalyst bodies 8 can be inserted axially one behind the other, with a ceramic ring 10 being expediently interposed between these catalyst bodies 8, in order to form a space acting as a mixing zone for the exhaust gases between successive catalyst bodies 8.

If necessary, a further pipe section, which encloses a catalyst body 8 in the same manner as the other two pipe sections 4 and 5, can be interposed between the pipe sections 4 and 5. Correspondingly, a housing section encasing a further catalyst body 8 can be arranged between the housing halves 22 and 23.

In all of these embodiments, the axial housing length can always be exactly the axial length of the successive catalyst bodies 8 and, if appropriate, the intermediate one Ceramic rings 10 are adapted by holding together the pipe sections or housing sections forming the housing 1 with sufficient axial thrust force, while the pipe sections or housing sections are connected to one another.

In particular, the type shown in FIG. 1 is characterized in that for adapting to exhaust systems of different internal combustion engines, it is easily possible to manufacture housings 1 with different dimensions for differently sized catalyst bodies 8 and different spacer rings 10. In essence, it must only be assumed that the housing is manufactured in accordance with differently dimensioned tubes.

In any case, changing the axial dimensions of the housing is particularly easy.

In all the embodiments shown above, it is advantageous that the housing sections 4 and 5 (cf. FIG. 1) or 22 and 23 (cf. FIG. 2) can be plugged together axially with very great force, in such a way that in each case that between the catalyst bodies 8 arranged ceramic ring 10 or the like. even if the end surfaces of the ceramic ring 10 or the catalyst body 8 are not exactly ground flat, adjoins the catalyst body 8 axially close by the ceramic ring 10 "digging" somewhat into the end faces of the catalyst body 8. This allows a very good seal between the ceramic ring 10 or the like. and reach the facing end faces of the catalyst bodies 8. The space between the successive catalyst bodies 8 encompassed by the ceramic ring 10 is accordingly well sealed off from the inflation mat 9.

The embodiment shown in FIG. 1 has the advantage that the inlet and outlet funnels 14, 15 can be modified without great effort - in particular without changing the parts encasing the catalyst body 8. This is advantageous when manufacturing prototypes or with regard to possible modifications during series production.

Claims (10)

1.Device for the catalytic cleaning or decomposition of hot exhaust gases, in particular an internal combustion engine, with a tube-like housing arranged or attachable in the exhaust gas flow and at least one catalytically active body (catalytic body) accommodated therein or coated with catalytically active material (catalyst body), which in the housing is held by means of a resilient mat encasing the body in an annular manner, which is formed at least within an area encircling the associated catalyst body as an inflatable mat consisting of a material which irreversibly swells under heat and which seals an annular spacing zone between the catalyst body and the wall of the housing, which zone consists of at least two axially assembled tube-like housing sections is constructed,
characterized, that stops (7, 25) are arranged in the housing (1) on the end faces of the catalyst body (8) or on the foremost and rearmost end faces of the successive catalyst bodies (8) in the flow direction of the exhaust gas, said stops overlapping radially, that the catalyst body (s) (8) with the associated mat (9) are inserted axially into the housing sections (4, 5; 22, 23) and the housing sections (4, 5; 22, 23) in one axial direction while compensating for manufacturing tolerances assembled state are firmly connected to each other (by circumferential weld seam 6), in which the stops (7, 25) bear against the assigned end faces of the catalyst body or the catalyst bodies (8) and, if appropriate, successive catalyst bodies (8) against one another or against spacers arranged between them (10) be pushed, and that a definable axial spacing space can be formed or formed by spacer elements (13, 29) inserted axially between the stops (7, 25) and the associated end faces of the catalyst body or the catalyst bodies (8) and burning or dissolving under the action of heat. 2. Device according to claim 1, characterized in that an annular surface (7.25) is arranged as a stop. 3. Apparatus according to claim 1, characterized in that the stops are each formed by the flank of a bead or a bead in the housing (1) or in a housing part (14 ', 15'). 4. Device according to one of claims 1 to 3, characterized in that annular disc-shaped inserts (13, 29) are arranged as spacing elements, e.g. made of combustible or heat-dissolving ceramic material. 5. Device according to one of claims 1 to 4, characterized in that between the successive catalyst bodies (8) in the flow direction of the exhaust gas, a spacing space remains as a mixing zone for the exhaust gases. 6. The device according to claim 5, characterized in that between the mutually facing end faces of the catalyst body (8) is arranged as a spacer, a ring part (10) which is held in the housing (1) by means of a resilient mat (11). 7. Device according to one of claims 1 to 6, characterized in that the or the catalyst body (8) and the ring part (10) are encased or held substantially over their entire axial length by means of inflatable mats. 8. Device according to one of claims 1 to 7, characterized in that filled by inflatable mats (9, 11) annular spaces between the catalyst body (8) or the catalyst bodies or the ring part and the housing (1) by sealing rings made of wire mesh (12 , 27, 28) are sealed. 9. Device according to one of claims 1 to 8, characterized in that the housing sections are designed as tubular pieces (4,5). 10. Device according to one of claims 1 to 8, characterized in that the housing sections (22, 23) are composed of shell parts.

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