DE102006038204A1 - Inlet funnel for an exhaust gas treatment device - Google Patents

Abstract

The The invention relates to an inlet funnel (1) for an exhaust gas treatment device for motor vehicles, with an inflow opening (4) which can be connected to an exhaust pipe (2) and one to the housing connect the exhaust device Outflow opening (5). To a flow separation of the inner wall of the inlet funnel (1) and the formation of vertebrae to avoid, within the entrance funnel is a diffuser (16) arranged, the away from the inflow opening (4) and in the extended Area of the input funnel (1) hineinerstreckt, wherein between Diffuser (16) and the inner wall of the inlet funnel one Ring channel (17) forming free space is present.

Description

The The invention relates to an inlet funnel for an exhaust gas treatment device for motor vehicles. Built into the exhaust system of a motor vehicle, a mostly catalytic effective element-containing exhaust gas treatment facilities serve For example, for the reduction of nitrogen oxides, for the oxidation of Hydrocarbons or for the removal of diesel particles the exhaust. An effecting such a cleaning effect element is for example one in the flow direction from a variety of fine channels traversed, mostly ceramic body, a so-called monolith on which will be referred to below by way of example. The specific ones Reactions are catalytically active substances, for example Platinum, reached on the walls the named channels are separated.

The Exhaust gas is supplied to said devices via an exhaust pipe, the usually has a smaller diameter than the housing of the Exhaust gas treatment device. The latter is therefore with the exhaust pipe over a Entrance funnel, which is usually a part of the housing, connected. The inlet funnel has an inlet opening which can be connected to the exhaust pipe, and one to the housing the exhaust gas treatment device connectable outflow opening. An exhaust gas flow passing through the inlet funnel is due to the Extension of the flow cross-section slowed down in return, increasing its static pressure. At with relative high speed streaming Exhaust gas is this effect, especially in the edge area, so the funnel wall near range of the exhaust stream most pronounced. The speed distribution over the Flow area seen changed So to the detriment of the edge regions of the exhaust gas flow. in addition There is another effect which significantly increases this tendency: the larger the Diameter difference between exhaust pipe and monolith or steeper the funnel wall runs, the bigger the tendency of an exhaust gas stream passing the input manifold, to detach from the funnel wall to form vertebrae. in the Edge region of the flow forms a more or less pronounced recirculation area. In addition to an elevated Pressure loss is another undesirable consequence of the uneven flow of the face of the monolith, which reduces its efficiency.

From that Based on the object of the invention, an inlet funnel to propose the type mentioned, with the technically simple Way, bypassed the disadvantages described or at least mitigated can be.

These Task is solved according to claim 1, characterized in that within the input hopper a diffuser is disposed extending away from the inflow opening and extends into the extended area of the entrance funnel, being between the diffuser and the inner wall of the inlet funnel a ring channel forming free space is present. By the Diffuser, so basically one in the flow direction opening Funnel, is the entering into the inlet funnel exhaust stream into two sub-streams, namely a guided through the annular channel edge or sheath flow and a central flow passing through the diffuser, divided. Of the Sheath flow is now limited inwardly by the outer surface of the diffuser, causing a flow separation and suppresses the formation of vertebrae is. The on the outside surface of the Diffuser impinging sheath flow will go outside deflected towards the funnel inner wall and retains this Direction even after leaving the ring channel without significant flow rate at. At the outflow opening or the inflow surface of the monolith is thus a uniform flow distribution present, leaving a monolith in relation to its flow area is flowed through evenly. Furthermore is reduced because of the lack of turbulence of the pressure loss in the inlet hopper.

at an advantageous fixation of the diffuser within the inlet funnel the former is middle or immediate by means of connecting elements is connected to the input hopper, wherein between in the circumferential direction one adjacent to the connecting elements in the annular channel opens Flow opening available is. By this configuration, on the one hand, a sufficiently strong Ensuring fixation of the diffuser at the inlet funnel. On the other hand, the Fasteners are designed so that they only a small Cover part of the flow cross section, so that the existing between adjacent connecting elements Flow openings relative be big and, accordingly, the edge or sheath flow of an exhaust gas flow nearly can enter the ring channel without hindrance.

In a further preferred embodiment, the connecting elements are designed as in the flow direction in the annular channel extending into wall elements. The wall elements act as the sheath flow stabilizing baffles. The wall elements can, but need not necessarily ge rectilinearly extend in the flow direction or in the direction of the central longitudinal axis of the input hopper. It is conceivable that it is curved or twisted in such a way that exhaust gas flowing into the inlet funnel is deflected with a movement component in the circumferential direction. Such a measure can be used to correct a Input hopper already be used with an uneven distribution reaching exhaust gas flow, such as when the inlet hopper is connected to a curved exhaust pipe. Furthermore, with this embodiment of the webs, the mixing of a possibly present uneven concentration of a reducing agent, as occurs in SCR systems, can be improved.

The Making an entrance hopper is facilitated by that the diffuser formed as a separate part and via the connecting elements with connected to a fixing element, with which he at the entrance funnel is attached. Entrance funnel and diffuser can be characterized independently each produce in a simple manner. In addition, let the entrance funnel already existing or in use retrofit existing exhaust treatment facilities with a diffuser. at a particularly preferred embodiment, the inlet funnel in the region of its inflow one Flange on. The above-mentioned fixing element the diffuser is also formed as a flange, the two Flanges parallel to each other and abut each other. A fixation of the flanges together, for example, with the help made by drilling in the flanges passing through screws. Such a diffuser is particularly suitable for the above-mentioned retrofitting. Instead of drilling can the flanges also with a clamping connection, e.g. with a V-clamp, get connected.

The The invention will now be described with reference to the accompanying drawings explained in more detail. Show it:

1 a schematic longitudinal section through a conventional input hopper, which is disposed between a flue-carrying pipe and an exhaust gas treatment device, such as a catalyst,

2 an illustration accordingly 1 but with an inlet funnel according to the invention,

3 a perspective view of the entrance funnel of 2 .

4 a longitudinal sectional perspective view of the input funnel of 3 .

5 a perspective view of an alternative embodiment of an inlet funnel.

An entrance funnel 1 serves, as has already been explained briefly above, to an exhaust pipe 2 smaller diameter or flow cross-section with an exhaust gas treatment device of larger diameter or flow cross-section to connect. The exhaust gas treatment device is, for example, a monolithic catalyst 3 , The entrance funnel 1 has a the exhaust pipe 2 adapted inflow opening 4 and on the output side, an outflow opening 5 on. Their size is to the to be acted upon with exhaust frontal Anströmfläche 6 adapted to a monolith. In the area of the inflow opening 4 is at the entrance funnel 1 a flange 7 arranged for fixing to a flange 11 of the exhaust pipe 2 serves. The discharge opening 5 is from a beaded edge 8th bounded, one in the flow direction 12 pointing, to connect with a catalyst 3 supporting housing serving end face 9 having. Of course, other configurations are conceivable here as well.

As in 1 with the help of arrows 10 has been attempted to clarify, an exhaust gas flowing in a cylindrical exhaust pipe essentially has a constant velocity profile over the flow cross-section. The arrowheads of the mentioned arrows accordingly end approximately on a transversely to the flow direction 12 extending imaginary line. So the inflow area 6 also in their the funnel edge 8th Exhaust gas is applied to near edge regions, and the exhaust gas flow must widen. Because of the usually very scarce space in an exhaust system, must be an inlet funnel 1 be relatively short. However, this means that its in the flow direction 12 extended funnel wall 13 relatively steep with respect to the flow direction 12 runs. The steeper now a funnel wall 13 is configured, the easier it dissolves an exhaust gas flow from its inside 14 which causes vortexes or recirculation areas 15 arise against the flow direction 12 have pointing currents. By this effect, on the one hand, the pressure loss of the exhaust stream in the inlet hopper 1 elevated. On the other hand, this results in a reduced flow velocity of the sheath flow. While a central area of the exhaust stream is the entrance hopper 1 Interspersed with almost undiminished speed prevails in the edge areas or in the funnel wall 13 Near areas of the exhaust stream before a reduced flow velocity. This is in 1 thereby clarifying that the arrowheads of the arrows 10a on a in the flow direction 12 bulging imaginary line 21 end up. This flow unequal distribution is also in the catalyst 3 away, which also there by appropriately sized arrows 10b and the imaginary line 21a is clarified. The one catalyst 3 or any other exhaust gas treatment device passing channels are thus with a different, optionally above or below its power limit applied exhaust gas per unit time.

To avoid such conditions, is within the in 2 shown inlet funnel according to the invention 1a a diffuser 16 arranged. This is essentially a widening in the direction of flow pipe section, so also a funnel-shaped structure. Between the diffuser 16 and the inside 14 of the entrance funnel 1 There is a radial clearance, whereby between entrance funnel 1a and diffuser 16 a ring channel 17 is formed. The diffuser 16 has a shorter length on the hopper area 19 the entrance funnel 1a in which it extends into it by a distance which is tuned in relation to the field of use and the actual geometrical conditions and, for example, is smaller than half the length 18 of the funnel area 19 , At the side of the funnel area facing the direction of flow 19 closes tubular or cylindrical section 20 with constant inner diameter or constant flow cross-section on. Also the diffuser 16 is not designed funnel-shaped over its entire length, but points next to a funnel area 22 join each other at this and against the flow direction 12 extending tubular section 23 with constant inside diameter or flow cross section. However, such a configuration is not mandatory and depends on the respective outer funnel.

The diffuser 16 is formed as a separate part, being against the flow direction 12 pointing end or the tubular portion 23 via web-shaped connecting elements 24 with a flange 25 is connected, the plane of the plane - seen in the assembled state - parallel to the plane Plane of the flange 7 of the entrance funnel 1a extends. The flange 25 of the diffuser 16 is in the assembled state hiss the flange 7 of the entrance funnel 1a and a flange provided on the exhaust pipe 31 locked in. A fixation of the three mentioned flanges via holes 32 ( 3 and 5 ), which are penetrated by screws (not shown). The connecting elements 24 are preferably uniformly distributed in the circumferential direction, wherein between adjacent connecting webs 24 one flow opening each 26 is available.

That over the exhaust pipe 2 in the entrance funnel 1a entering exhaust gas is through the diffuser 16 divided into two sub-streams, namely an outer, from the flow openings 26 exiting and through the annular channel 17 conducted jacket current 27 and one the diffuser 16 passing through central power 28 , The sheath current 27 meets after exiting the flow openings 26 on the outside 29 of the diffuser and thereby becomes outward toward the inside 14 of the entrance funnel 1a directed. In the areas where the entrance funnel 1 to 1 Vortex formed, thus a substantially uniform flow is forced and the formation of vertebrae 15 suppressed what is in 2 through the arrows 10c is indicated. The the diffuser 16 passing through central power 28 learns according to the funnel shape of the diffuser 16 a radial expansion, but with a stall on the inside of the funnel area 19 because of the small length of the diffuser 16 is not to be feared. A uniform flow and thus the suppression of vortex formation in the sheath flow 27 is still supported by the fact that in the ring channel 17 a bottleneck 30 is available. This arises from the fact that the funnel area 22 of the diffuser 16 in the tubular section 20 of the entrance funnel 1a hineinerstreckt.

In 5 is an embodiment of a diffuser 16a shown in which to the fasteners 24 and the outside 29 one each a flow direction 12 or in the direction of the central longitudinal axis 33 of the diffuser 16a extending, the sheath flow 27 stabilizing wall element 34 is formed.

Claims (6)

Entrance hopper for an exhaust gas treatment device for motor vehicles, with a to an exhaust pipe ( 2 ) connectable inflow opening ( 4 ), and a connectable to the housing of the exhaust device discharge port ( 5 ), characterized in that inside the inlet funnel ( 1 ) a diffuser ( 16 ), which extends from the inflow opening ( 4 ) away and into the extended area of the entrance funnel ( 1 ), wherein between diffuser ( 16 ) and the inner wall of the inlet funnel an an annular channel ( 17 ) forming free space is present. Inlet funnel according to claim 2, characterized in that the diffuser ( 16 ) by means of connecting elements ( 24 ) directly or indirectly with the inlet funnel ( 1 ) is connected, wherein between adjacent circumferentially adjacent connecting elements in each case one in the annular channel ( 17 ) opening flow opening ( 26 ) is available. Entrance funnel according to claim 2, characterized in that the connecting elements ( 24 ) Are wall elements that are in the flow direction ( 12 ) in the annular channel ( 17 ) extend into it. Entrance hopper according to claim 3, characterized in that at least one end portion of the wall elements such curved or twisted is that in the entrance funnel ( 1 ) inflowing exhaust gas is deflected with a component of motion in the circumferential direction. Inlet hopper according to one of claims 2 to 4, characterized in that the diffuser ( 16 ) formed as a separate part and via the connecting elements ( 24 ) is connected to a fixing element with which it is attached to the inlet funnel Inlet funnel according to claim 5, characterized in that the inlet funnel ( 1 ) in the region of its inflow opening a flange ( 7 ), and that the fixing element of the diffuser ( 16 ) also as flange ( 25 ) is formed, wherein the flanges ( 7 . 25 ) parallel to each other and abut each other.