DE3517035C1 - Matrix for a catalytic reactor for exhaust gas cleaning - Google Patents

Description

or are not that easy to manufacture.

In a particularly simple embodiment of the invention, the cross-sectional weakenings are incisions have been formed, which cut through the sheet steel strip from one side to a distance that corresponds to its material thickness. The incisions are based on the material used and its deformability coordinated so that the remaining connecting strips, which are parts of a duct wall, be bent by 180 ° and take over the axial securing of the layers lying on top of one another. Particularly In such an embodiment, it is of course advantageous if the corrugations of the sheet steel strip have a Form a trapezoidal cross-section for the channels, so that three channel walls are cut in each case and the remaining channel wall forms the connecting strip.

It is also possible to provide the channel walls with punched-out tabs to increase the turbulence, which protrude into the interior of the channels, or to provide additional openings in the channel walls, This can also be used to balance the flow between the individual channels. Such a Compensation is also possible if the channels and thus the channels in the area of one layer in the longitudinal direction are divided into areas of different heights, with at least two areas with the greatest height than System for the adjacent location. In doing so, the area with low altitude can thereby be formed that the steel strip is pressed flatter at this point than in the other areas. The production of the new steel strip can also be done largely automatically. First of all Pulled a flat steel band between rollers and in doing so in the direction of pull with the desired Provide corrugations, then cut in certain sections and then in a zigzag shape folded on top of each other. During this rolling process, the intermediate areas can also be flattened so that no separate effort for the production of the sheet steel strip and for its subsequent Must be forced to fold onto one another to form a matrix.

The invention is based on two exemplary embodiments shown in the drawing and is described below.

It shows

Fig. 1 is a schematic perspective view of a Part of a new longitudinally corrugated sheet steel strip, which in certain sections of Is divided into folding levels,

F i g. 2 the sheet steel band of FIG. 1, but with one section in a folding plane opposite the other is folded up or folded,

3 shows the section through the sheet steel strip of FIG. 2 in the direction of level III-III,

4 shows a schematic and perspective illustration a cuboid formed by folding the various sections of FIGS. 1 and 2 on top of one another Matrix,

F i g. 5 shows a representation similar to FIG. 1, but in another embodiment, here only the area of the sheet steel strip is shown, which corresponds to a section

6 shows the section through the section of the sheet steel strip the F i g. 5 in the direction of plane VI-VI,

F i g. 7 shows a schematic plan view of a matrix suitable for forming a non-cuboidal matrix Sheet steel tape,

F i g. 8 shows a comparison with the illustration in FIG. 7 enlarged sectional view through a sheet steel strip from FIG. 7 formed matrix and
F i g. 9 the top view, also schematically, of the matrix of FIG. 8th.

In FIG. 1 shows a section of a sheet steel strip 1 which is provided with corrugations in its longitudinal direction, each of which forms channels 2 with a trapezoidal cross-section, which are delimited by the channel walls 3, 4 and 5. At the distance a, the sheet steel strip 1 is divided into sections 1 a, \ b , etc., the boundaries of the sections being formed by folding planes 6 indicated by dash-dotted lines, which run perpendicular to the longitudinal direction of the channels 2. In these folding planes 6, the sheet steel strip 1 is provided with incisions 7 from one side, in the exemplary embodiment from the underside, up to a distance b, which corresponds to the material thickness of the steel strip 1, which cut through the sheet steel strip 1 except for a strip 8 which is part of the top wall 3 of each of the individual channels 2.

If now, according to FIG. 2 and 3, a section of the steel strip, for example section Ib, is folded over by an angle of 180 ° in the direction of arrow 9 with respect to the other section, for example la, the connecting strip 8 is deformed accordingly, but after folding it is together with the other connecting strips on the other channels represent a stable connection point for the adjacent layers la, \ b, Xc , etc. of the matrix 10, which is indicated in FIG.

When folding over, which follows zigzag in one or the other direction, due to the superimposition of the respective channel walls 3, 3 'channels 12 with a honeycomb cross-section, which are then traversed by exhaust gas in their longitudinal direction in the direction of arrow 13. The cross section the channels 12 therefore corresponds to twice the cross section of the channels 2, which are folded over the sections la, 16 etc. to the honeycomb channel cross-section add to. The new embodiment of the matrix 10 offers good utilization of the surface, which can be further improved in that the area of the channel wall 3, 3 'is as small as possible is made. Of course, sheet steel strips with a different wave cross-section can also be provided, as long as there is a guarantee that enough bars remain when incisions are made, which can be folded over and after being folded for a stable cohesion of the individual on top of each other folded layers.

FIGS. 5 and 6 show another embodiment in which the sheet steel strip used as the starting material, which is shown here only in a section 1 a ', is provided with grooves 2' with different heights in their longitudinal direction arrows 13. In the exemplary embodiment, this has been achieved in that the band 1 of FIG. 1 is pressed flatter in the production of the corrugations in the intermediate areas 14 than in the two areas 15 in front of and behind it, so that at these points there are channel sections which are wider in cross-section but flatter in height, which can be seen from FIG. 6 can also be seen. This is because the area 15 with the height h merges into a wider area 14, which however only has the height /. When laying sections on top of one another, such as the

Sections la 'and if, the latter being indicated by dashed lines in FIG. 6, there are openings 16 running transversely to the longitudinal direction in the area of the mutually adjacent walls, which allow exhaust gas to pass transversely to the direction of flow 13 from one channel 12 to the other enable. This leads to good mixing and to a more uniformity of the flow profile within the matrix, which is one of the decisive factors for the catalytic efficiency of the reactor.

To improve the mixing and to achieve the highest possible level serving this purpose The degree of turbulence in the flow can, as is also provided for with other types of construction, from the Side walls 4, 5 of the channels 2, 2 'each tab 17 punched out into the channels 12 or the channels 2.2 'stand in. Are created at the punched-out points Breakthroughs 18, which are also used for a passage of gas from one channel into the neighboring Channel can serve.

In the F i g. 7 to 9 an embodiment of a matrix is shown which, deviating from the matrix of FIG F i g. 4, does not have a cuboid shape, but for the formation of exhaust gas reactors with oval, possibly also round Cross section can be provided.

F i g. 7 shows schematically the formation of a sheet steel strip 20, which has the outer contour of two trapezoids each coinciding with their larger base lines 21, the smaller base line 22 of which is assigned to the end of the sheet steel strip 20 and whose side surfaces 23 and 24 each have the width A \ bis diverge to the greatest width A _2. The side surfaces 23 'and 24' of the second trapezoid, which is designed and arranged symmetrically to the trapezoid 21, 20, 24, 22 with respect to the base line 21, run analogously. In each case at a distance of all from the base line 21, the folding planes 6 are arranged in this sheet steel band 20, which, as in the previously described embodiments, are again arranged at equal distances a from one another over the length of the sheet steel band 20. The rest of the training corresponds to the embodiment of FIG. 1 and 2. Folding at the folding planes 6 does not result in cuboid bodies, the cross-section of which is shown in FIG. 8 is indicated, for example. It can be seen that the individual sections 20a, 206 are stacked on top of one another by folding them in a zigzag manner. Since their width is getting smaller and smaller due to the trapezoidal shape of the steel strip sections, a matrix is created, the cross section of which corresponds approximately to the oval shape 25 of FIG. The greatest width of this oval cross-sectional shape corresponds to the greatest width Λ2 of the sheet steel strip 20. The smallest width A \ is reached at the two outer ends. The smallest trapezoidal sections 20c - see FIG. 9 - each lie on the outside of the matrix. The middle portion 20a is arranged in the middle.

As shown in FIGS. 7 and 8, the division of the corrugated cross-sections of the strip changes from the largest division ti to the smallest division t \ in this embodiment. If necessary, however, it would also be possible to produce the band 20 with the same corrugation pitch, namely if a steel band is used as the starting point, as shown in FIG. 1 is shown and if only the outer contours are then trimmed.

It is of course also possible in principle to provide a different corrugated cross-section in each case instead of the illustrated trapezoidal cross-section of the corrugations with the division ii or ti , as was already provided in principle in other known matrix shapes. The only decisive factor is that the corrugated cross-section must be such that, after the incisions 7 have been made, there is still enough material to hold the band to be folded together.

For this purpose 3 sheets of drawings

Claims (12)

1 2 door of two patent claims, each with their larger basic lines: (21) has coincident, symmetrically formed trapezoids and that the FaIt- 1. Matrix for a catalytic reactor for leveling (6) each at the same distance (a / 2) from gas cleaning, in particular for internal combustion engines 5 of this base line (21) are arranged. NEN, consisting of a corrugated and catalyzed 13. Matrix according to claim 11, characterized by Satormaterial coatable sheet steel tape that draws in that the corrugations have a different several layers in a zigzag pattern one on top of the other- division (tu t- £) over the length of the steel strip (20) folds and is held in a housing that has in. Longitudinal direction of the io formed by the corrugations The exhaust gas flows through the ducts, thereby indicates that the sheet steel band (1, 20)
has grooves (2, 2 ') formed by the corrugations, along transversely to the longitudinal direction of the groove for cutting weaknesses and in these FaIt internal combustion engines, consisting of a corrugated flat sheet steel that can be coated with catalyst material, is folded by 180 ° at the remaining connection points, so that the grooves form Kanä- band that are superimposed in several layers in a zigzag shape (12). derfolded and held in a housing that is in 2. Matrix according to claim 1, characterized in that the longitudinal direction of the edge formed by the corrugations is that the distance (a) of the folding planes (6) is in each case flowed against by the exhaust gas. is the same size. It is known that from corrugated sheet steel strips 3. Matrix according to claims 1 and 2, characterized in that the matrix for reactors of the above-mentioned type is produced, that the folding planes (6) under a len (DE-PS 27 33 640). Each will be smooth Angle of 90 ° to the longitudinal direction (13) of the gutters 25 steel strips and corrugated strips with each other gewiklauf. kelt. It is also known (DE-OS 29 02 779) to increase 4. Matrix according to claim 1, characterized in that the cross-sectional weakening is formed as a single-matrix strip of corrugated metal sheets on smooth cuts (7), which are to be attached by sheet steel strips or they are side by side wind up the sheet steel band (1) up to an unwinding 30. In all cases, the matrix must be severed after the stand (b) , the winding of its material thickness, so that the individual layers correspond. do not slip among each other. 5. Matrix according to claim 4, characterized marked- A matrix of the type mentioned is also net that the incisions (7) have a width that has already been proposed. With her one becomes, with one on the material used and its deformability 35 trapezoidal cross-section in its corrugations, and is matched to the material thickness. steel strip along one of its 6. Matrix according to one of claims 1 to 5, da- edge, that is, in a direction that is parallel to that of ^. characterized in that the corrugations run in a zigzag-specific channel formed by traditional corrugations Form cross-section for the channels (2), folded onto one another in a shape. The cross-sectional shape of the that three gutter walls (4, 5 and 3a) in 40 corrugated tape is chosen so that the one another the folding planes (6) provided with the incisions (7) lying channel walls are each larger than the have been and that the remaining connection is the distances between them. This is supposed to be a put a strip-shaped part (8) of the fourth channel - avoiding slipping of the individual layers into one another wall (3,3 ') is. will. Even with this matrix, however, provisions 7. Matrix according to one of claims 1 to 6, since 45 ments are taken to be parallel to the later characterized in that the channel walls (4, inflow direction folded layers against each other in 5) are provided with punched-out tabs (17) to secure the direction of flow. This usually happens protrude into the interior of the channels (12). by soldering. 8. Matrix according to claim 7, characterized marked- The invention is based on the object of a Manet, that openings (18) in the Rinnenwän- 50 trix of the type mentioned to form that a the (4,5) are provided. Soldering process is not necessary and that by joining 9. Matrix according to one of claims 1 to 8, there- fore already fold a sufficiently stable matrix, characterized in that the grooves (2 ') exist, which are only coated with catalyst material, rich in a layer (ia') in the longitudinal direction ( 13) must be ready. before (14, 15) of different heights were subdivided 55 To solve this problem, the identifiable are, wherein at least two areas (15) with nenden features of claim 1 are provided. By of the greatest height as an attachment for the adjoining this configuration remain transversely to each layer Position (l b ') are provided. because it runs on both ends and over the 10. Matrix according to claim 9, characterized in that the entire width of the matrix is characterized by a continuous connection between two areas (15) with the 60 which are sufficiently stable to hold a flattened housing at a maximum height (h) Matrix without an additional area (14) of lower height (flies, working process to hold tightly together. The distance 11. Matrix according to claim 1 and 2, characterized in that the folding planes can be selected to be the same size in each case that the sheet steel strip (20) is up to one, so that the matrix after folding has a square maximum width (A2) diverging outer cones - 65 or cubic shape. The new Ausgestalturen (23,24,23 ', 24') has. tion is particularly suitable for the formation of non 12. Matrix according to claim 11, characterized in that round matrix shapes are wound with or in the shows that the sheet steel band (20) does not have the outer con - previously described folded bands - *