DE3120212A1 - Inlet funnel for devices through which gas can flow - Google Patents

Abstract

In order to obtain a uniform flow over the entire cross-section for the inflow of gases, in particular the exhaust gas of internal combustion engines, into a silencer, in which case the cross-section at the inlet can be circular and the transition to the silencer can be roughly oval, impressions are provided at at least approximately opposite locations in the inlet funnel. These impressions can also be made in the inlet funnel in several planes, e.g. at right angles to one another. The back pressure, among other things, on the engine is reduced by this evening-out of the flow. During combustion processes, the combustion of the fuel/air mixture is thereby improved.

Description

Inlet funnel for gas flowing through

bare devices The invention relates to an entry funnel for devices through which gas can flow, such. B. Filters, silencers, combustion chambers or catalytic treatment devices, one of an initial cross-section with at least approximately the same width in two mutually perpendicular Directions, especially from a circular cross-section, steadily into a much larger one End cross-section with widely different widths in these two directions all in an oval cross-section and the facilities for influencing, in particular to even out the flow at its end cross-section.

In filters, silencers and catalytic treatment devices A uniform flow over the entire cross-section is crucial Significance for a satisfactory effect. At the roughly circular Initial cross-section of the flow-favorable transition to the approximately oval end cross-section causing the funnel, there is a rather uneven flow that flows from the upstream gas generation systems also occasionally promotes a Irregular shape of such an inlet funnel given for installation reasons an uneven flow distribution. On the other hand, it can be zoBo For thermal or ignition reasons, the flow may be desirable to keep unevenly across the cross-section in a special way.

For these reasons, the flow was previously used to influence the flow or circular grids or thresholds are used9 However, these are either Little effective or quite costly inventive task is therefore an entry funnel of the type listed so that in each application at his End cross-section a desired flow distribution is obtained9 This task is solved with the characterizing feature of claim 1, preferably on opposite sides Places of the funnel made indentations, their shape and position experimentally is confirmed, direct the flow into the desired direction without significant loss Tracks they are especially with pressed funnel shells in the same pressing process easy to manufacture and can be attached practically anywhere.

Claims 2 and 5 to 9 give preferred shapes of the indentations to, while claims 3 and 4 anyway up to 12 special layers affecting dents.

If the indentations are in opposite places, e.g. in the middle of the funnel length, attached in the short cross-sectional axis, so becomes the flow is pushed into the outer areas of the long cross-sectional axis and thus evened out over the end cross-section. Palls required can cause such dents also attached in several levels, e.g. in two levels at right angles to each other be. In special palls, of course, several indentations can be made in the direction of flow lying one behind the other.

The dents do not need one another according to shape and size to be the same. A common form of indentation is a cone with, for example, a 60 ° cone angle. For the flow, however, it is generally more favorable on the downstream leg in the longitudinal section the angle of inclination in relation to the perpendicular to the funnel axis to be formed much larger than on the upstream leg, as this creates a a laval-nozzle-shaped indentation arises. Likewise, the angle of inclination of the two legs may be different from each other in cross-section, if this is the flow favorably influenced.

In some cases there is an indentation shaped like a shock diffuser in the longitudinal section cheap; the angle of inclination of the downstream leg with respect to the vertical to the funnel axis is then much smaller than that of the upstream leg. The downstream leg of the indentation triangular in longitudinal section can then, e.g. on one side, in a leg with an oppositely directed, however much larger Ignore the angle of inclination what turns out to be special If the inlet funnel9 has proven advantageous, e.g. for reasons of installation, a Center offset from the initial cross-section in the longitudinal direction and / or transverse direction of the end cross-section on 9 and the central axis runs obliquely, curved or broken what is often the case with sound absorbers of motor vehicle engines, the Dents with advantage not in the area of its longitudinal center plane but closer attached to the outer or longer side of the shell9 Entrance funnel from preferably mirror-inverted at least approximately the same, shells formed by seizure assembled; these are at their beaded edges, which lie in a plane passing through the large cross-sectional axis, with one another welded9 The indentations are formed in at least one shell and molded at the same time as they are pressed; if necessary, they can go beyond the level the edge of the stock exchange reach into the other shell9 from the aerodynamic For reasons, the corners of the dents are always strongly rounded.

The invention is further explained with reference to the drawing; thereby shows FIG. 1a shows an inlet funnel according to the invention in a side view, FIG. 9 ib in a front view namely in the direction of flow A and Fig. 1c in plan view; Fig. 2 a cross-section B-B through such an entry funnel with two opposite one another conical indentations and FIG. 3 with four indentations; Fig. 4a another Inlet funnel according to the invention with two opposing triangular shapes Indentations in the longitudinal section and FIG. 4b with their different angle of inclination in cross section; Fig. 5a such an entry funnel, the indentations however, have the shape of a triangle with a different angle of inclination, and although in longitudinal section and FIG. 5b in cross section; 6 shows such an entry funnel according to Fig. 4 or 5, the downstream legs of the triangular indentations however, a smaller angle of inclination with respect to the perpendicular to the funnel axis have and in one leg with oppositely directed and much larger Skip the angle of inclination; 7a with an inlet funnel according to the invention offset from the initial cross-section in the longitudinal and transverse directions Focus of the end cross-section and with an oblique and slightly curved longitudinal central axis, namely in side view9 Fig9 7b in front view and Fig9 7c in plan view, Fig. 8 shows a cross-section in flow direction A of one of two only approximately in a mirror image the same shells composite inlet funnel according to the invention with different 9 to its longitudinal center plane laterally offset opposite indentations 9 According to Fig. 1, the jacket 1 is the one for e.g. a catalytic treatment device 7 for gases leading inlet funnel with a circular initial cross-section 5 and an oval end cross-section adapted to the cross-section of the device 6 provided; the final cross-section is about eight times as large as the initial cross-section the transition is straight forward. The central axis of the funnel is aligned with the treatment m device9 The funnel points to influencing the flow at its end cross-section indentations at opposite points of its flat curved shell part 2 from through experiments determined shape and size to 9 in the example shown they equalize the flow over the cross-section9 accordingly from the middle to push outside9 According to Fig.9 2 the indentations have the shape of a cone from about 600 cone angles, with strongly rounded edge areas.

According to Fig. 3 are in two mutually perpendicular planes, namely along the short cross-sectional axis I and along the long axis II, indentations 2 or 2a mounted opposite one another, whereby the flow over the cross-section can be influenced even more and more precisely.

According to Fig. 4, the indentations have both an I, longitudinal section as also a cross section of the shape of an isosceles but different Triangle with strongly rounded corners; the angle of inclination ß in relation to the The vertical 9 of the funnel axis 8 is much larger in the longitudinal section than the angle of inclination q in the cross section. This is the prevailing flow conditions Taken into account.

According to Fig. 5, the indentations each have the shape of a different unequal triangle; the angle of inclination β1 is the upstream one in the longitudinal section Leg s1 with respect to the perpendicular 9 of the funnel axis 8 is smaller than the angle of inclination ß2 of the downstream leg s2, creating an approximately laval nozzle-shaped, more streamlined Course of the narrowing is achieved. The angles of inclination o (1 and «2 in cross section are designed differently to compensate for cross flows.

After Pig. 6 is the angle of inclination ftt2 in the longitudinal section the downstream leg s2 in relation to the perpendicular 9 to the funnel axis 8 is essential smaller than the angle of inclination 0 1 of the upstream leg thereby an approximately Impact diffuser-shaped course of the constriction with known flow dynamic behavior is achieved. At the same time there is another and much weaker dent, in the example one-sided, downstream; in this way it is achieved that in the I. longitudinal section the downstream leg s2 of the triangular indentation into a leg s3 with an oppositely directed, substantially larger angle of inclination in the longitudinal section t passes over to the funnel axis 8 in relation to the vertical line 9 '; this has turned out to be proven to be particularly aerodynamic.

Npch Fig. 7 is the center of the initial section 5 of the entrance funnel 1 offset to the center of the end cross section 6 in the longitudinal direction and in the transverse direction arranged; the initial cross-section lies in a plane that is inclined to the final cross-section, the central axis being slightly curved in side view and roughly straight in plan view and is inclined to the central axis of the connected device. The one in the Longitudinal center plane I opposing indentations 2 are for the purpose of comparing not in this plane I but closer to the long side of the shell 19 because of the by no means uniform flow here over the cross-section.

According to FIG. 8, the entry funnel is only approximately made up of two mirror images of the same shells, which 3B94 'at their flanged edges connected by welding 9 The lower shell 4 is formed somewhat deeper than the upper shell 3.

Each shell has an indentation 2 or 2a; in the lower shell it is deeper, so that it goes over the parting plane passing through the flanged edges 3 ', 4' III reaches out. The indentations have the cross-sectional shape of a non-isosceles Triangle with the different angles of inclination α1 and α2 or α3 and with strongly rounded corners and are asymmetrical to the longitudinal center plane I, namely closer to the long side of the coat.

Claims (9)

Patent claims ========= - ====== 1 == I ======== c) i. Entry funnel For devices through which gas can flow, such as filters, silencers, combustion chambers or catalytic treatment devices, one of an initial cross-section with at least approximately the same width in two mutually perpendicular Directions, especially from a circular cross-section, steadily into a much larger one End cross-section with widely different widths in these two directions everything merges into an oval cross-section and Heinrich tungen to influence in particular to make the flow uniform at its end cross-section, characterized in that preferably on at least approximately opposite one another Places of the funnel jacket (1) indentations (2) are attached. 2. Entry funnel according to claim 1, characterized in that in the funnel jacket (1) in several planes, e.g. at right angles to one another (I, II) indentations are attached (Fig. 3). 3. Entry funnel according to claim 1 or 2, characterized in that that several indentations are attached one behind the other in the direction of flow (Fig. 6). 4. entry bar according to one of claims 1 to 3, characterized in that that the indentations are designed differently according to size and / or shape. 5. Entry funnel according to one of claims 1 to 4, characterized in that that the indentations have the shape of a cone of preferably about 600 cone angles have (Fig. 2). 6. Entry funnel according to one of claims 1 to 4, characterized in that that the indentations have a longitudinal section and / or a cross section of the Porm a triangle with different leg lengths and angles of inclination (p or p)) with respect to the perpendicular (9) to the funnel axis (8) and with strongly rounded Have corners (Fig. 4a, 4b). 7. entry funnel according to claim 6, characterized in that at least one of the indentations in the longitudinal section and / or cross-section the shape of a triangle with different angles of inclination («1« 2 or ß1, 2) in relation to on the perpendicular (9) to the funnel axis (8) has Fig. 5a, 5b). 8. entry funnel according to claim 6, characterized in that in the longitudinal section of a triangular indentation, the angle of inclination (P2) of the downstream Leg (s2) much larger than the angle of inclination (§1) of the upstream Leg (S1) is (Pig. 5a). 9. entry funnel according to claim 69, characterized in that in the longitudinal section of a triangular indentation, the angle of inclination (p2) of the downstream Leg (s2) much smaller than the angle of inclination (ß1) of the upstream Leg (S1) is (Fig. 6) '. 100 entry funnel according to one of claims 8 and 9, characterized in that that the downstream leg (s2) of the triangular indentation in leg (S3) with 9 facing in the opposite direction in the longitudinal section, but much larger Inclination angle (#) skips (Fig. 6). 119 Entry funnel according to one of Claims 1 to 109 with the initial cross-section in the longitudinal and / or transverse direction offset center of the end cross-section and characterized9 with obliquely9 curved or broken longitudinal center axis9 that the indentations (2) not in the area of its longitudinal center plane (I) but closer on its outside or longer shell side (1 ') are attached (Fig. 7). 12. Entry funnel according to one of claims 1 to 11, consisting from preferably mirror-inverted at least approximately the same shells that at their beaded edges, which go through the large cross-sectional axis Lying flat, connected to each other, zoBo are welded9 characterized by that the indentations (2) are formed in at least one shell and if necessary. Up to extend beyond the level (III) of the beaded edges into the other bowl (Fig. 8).