DE102013012909A1 - mixing chamber - Google Patents

Abstract

The invention relates to a mixing chamber 1 for mixing an additive in an exhaust system of an internal combustion engine a) with a single or multi-part housing 11, which has an inlet opening 12 for exhaust gas with a flow cross section S12 and with a central input axis M12 and a downstream of the input opening 12 Output outlet 13 for exhaust gas having a flow cross-section S13 and having a central outlet axis M13, wherein b) within the housing 11, a flow guide 2 between the two openings 12, 13 is arranged, wherein c) the flow guide 2 is tubular and at least one channel axis K2 having channel 20 with an inlet 22 and with an outlet 23, through which the entire exhaust gas flow in a direction parallel to the channel axis K2 flow direction S is directed to the outlet opening 13, where d) the flow direction S relative to the central exit axis M13 by an angle a between 20 ° and deviates 80 °.

Description

The invention relates to a mixing chamber for mixing an additive in an exhaust system of an internal combustion engine with a single or multi-part housing. For this purpose, the housing has an inlet opening for exhaust gas with a flow cross section and with a center input axis and an outlet opening for exhaust gas with a flow cross section and with a center outlet axis arranged downstream of the inlet opening. In the housing, a flow guide is arranged between the two openings.

It is already in the DE 11 2010 002 589 T5 a arranged between two monoliths (substrates) mixing chamber described. This mixing chamber is disposed between an upstream and downstream monoliths arranged in series for treating the exhaust gases circulating in the exhaust line. The mixing chamber has a channel formed by a shell and circulating around the central axis for the circulation of the exhaust gas flow, which is at least 20% longer than the mixing chamber along the central axis.

The object of the invention is to design and arrange a mixing chamber in such a way that, with a reduced overall length, an improved distribution of the mixture of exhaust gas and additive on the substrate surface and at the same time deposits of the additive are achieved.

The object is achieved according to the invention in that the flow guide is tubular and at least one duct having an inlet and an outlet, via which the entire exhaust gas flow is directed in a direction parallel to the channel axis flow direction to the exit opening, the flow direction relative to the central exit axis by an angle a between 20 ° and 80 ° deviates. The angle a is preferably between 55 ° and 75 °. At an angle of 65 °, wetting of the substrate with gamma greater than 0.9 was achieved.

It is thereby achieved that all the flow filaments of the exhaust gas flowing into the inlet opening are deflected by the flow guide element such that all flow filaments are led out of the mixing chamber through the flow guide element in approximately the same direction of flow as the outlet opening at which a downstream substrate is arranged. Since the exhaust gas is distributed over the flow area of the outlet opening, it is also distributed over the cross section of the downstream substrate. The downstream substrate is thus flowed obliquely over its entire end face with flow lines parallel to the flow direction, resulting in a very good distribution of the introduced in the mixing chamber additive, without the additive forms larger deposits. Under approximately parallel to the flow direction, the expert understands deviations from the flow direction defined as the main flow direction of a maximum of 5 ° to 8 °.

It can also be advantageous for this purpose if the outlet has an outlet cross-section extending at right angles to the central exit axis, wherein the outlet cross-section is at most 20% larger or smaller than the flow cross-section of the outlet opening and / or the channel axis the center exit axis at an angle a between 20 ° and 80 ° cuts. The flow guide collects all flow filaments and channels them in the direction of the outlet opening, wherein the additive is added to the exhaust gas flow in the flow guide.

For this purpose, it is advantageous for the flow guide element in the direction of the channel axis to have an inlet with an inlet cross-section opposite the outlet, whose size is reduced by 10% to 70% relative to the outlet cross-section. In addition to adapting to the respective hydraulic cross sections of the downstream and upstream substrates can be achieved with a reduction of the inlet cross-section acceleration of the exhaust stream at the inlet of the channel, starting in the channel, through which the introduced in the region of the inlet additive mixed better and in his Droplet size is reduced.

For this purpose, it is provided that the channel is sheathed by a channel wall and the channel wall is closed or perforation-free, so that the described deflection of all flow threads can be done. The inlet and the outlet thereby form the only openings of the flow-guiding element.

It can be advantageous in particular if the channel along the channel axis, starting at the central exit axis, has a length which corresponds at least to the quotient of a mean radius of the input opening to sinus a, ie L2 ≥ ^R12 / _sina . As a result, the flow guide element closes the flow cross section for the exhaust gas in the direction of the central input axis and forces it first from the axial direction into a radial direction before the exhaust gas flows into the flow guide element.

If the cross-sectional area of the upstream substrate is smaller than the flow area of the entrance opening to a certain maximum extent, then the channel has a reduced length which is at least the quotient corresponds to a mean radius of a substrate to sinus a, ie L2 ≥ ^R51 / _sina .

It is advantageously provided that the housing has a over the flow cross-section in the radial direction to the central input axis protruding dome, which at least partially forms the channel or at least partially protrudes into the channel. So that the outermost current thread can be deflected in the radial direction, the dome forms a volume outside the radial limits of the rest of the housing.

Of particular importance for the present invention may be that one or more mixing elements for mixing the injected into the mixing chamber additive are arranged on the channel to the inlet and / or in the channel. Regardless of whether the inlet is formed by a single opening or by a plurality of slots or a perforation through which the exhaust gas is swirled as it flows into the channel, mixing elements are provided downstream of the injection device.

In connection with the design and arrangement according to the invention, it may be advantageous if an injection device is arranged on the dome or on the flow guide, which introduces the additive in an injection direction in the flow, wherein the injection direction is employed by up to 90 ° to the channel axis. By a possible employment to the channel axis of the additive can be injected with or against the flow direction of the exhaust gas.

It can also be advantageous if the cross section of the channel increases continuously from the inlet to the outlet.

In addition, it may be advantageous if the housing and the downstream converter housing and / or the upstream converter housing form a one-part or multi-part common component.

Furthermore, it may be advantageous if the mixing element is a static mixer with one or more mixing stages.

Finally, it may be advantageous if the flow cross section of the inlet opening is different from the flow cross section of the outlet opening.

It can also be advantageous if the mixing chamber or the flow-guiding element or parts thereof are at least partially catalytically coated on the sides facing the exhaust gas.

The arrangement is particularly advantageous when the upstream substrate is designed as a catalyst and the downstream substrate as a particle filter.

Further advantages and details of the invention are explained in the patent claims and in the description and illustrated in the figures. It shows:

1 a sectional view of an embodiment with ankajte injection direction;

2 a sectional view of an embodiment with coaxial injection direction;

3 a schematic diagram of the geometric relationships;

4 a sectional view opposite to the flow direction according to sectional plane A-A ';

5 an embodiment with a mixing element in a flow guide with a slot-shaped inlet;

6 an embodiment with a conical flow guide;

7 an embodiment with a perforated flow guide;

8th an embodiment with parallel staggered substrates;

9 an embodiment with obliquely arranged substrates;

10 an embodiment with parallel in the radial direction juxtaposed substrates.

The 1 and 2 show a mixing chamber 1 placed between a downstream converter housing 4 and an upstream converter housing 5 is arranged. The mixing chamber 1 has a housing 11 with an entrance opening 12 and an exit port 13 which are arranged coaxially according to these two embodiments with respect to a central input axis M12 and a center output axis M13.

One between the entrance opening 12 and the exit port 13 arranged tubular flow guide 2 causes the exhaust gas flow after entering through the inlet opening 12 is deflected from an axial direction along the central input axis M12 in the radial direction, because the flow guide 2 an axial flow cross-section S12 blocks.

For this purpose, the flow guide 2 as a channel 20 with a channel wall 21 trained and closes with his outlet 23 against the flow direction to the outlet opening 13 of the housing 11 at. As an outlet cross-section A23 of the outlet 23 essentially a flow cross-section S13 of the outlet opening 13 corresponds, is the exit port 13 through the flow guide 2 closed in the direction of the central input axis M12. The exhaust gas flow will be after radial deflection via an inlet 22 in the channel 20 directed and at an angle a of 65 ° from the exit opening 13 on an end face of a downstream substrate 41 directed.

So that all possible flow threads at the end of the channel 20 Aligned approximately in a flow direction S parallel to a channel axis K2, the channel has 20 or the flow guide 2 a certain length L2, so that the outermost stream of thread is deflected in the radial direction to the outside.

The deflected in the radial direction exhaust gas stream collects in a dome 14 passing through a part of the case 11 is formed, in the radial direction over the inlet opening 12 also available. The inlet 22 the flow guide 2 is in the cathedral 14 arranged. At the cathedral 14 is in the area of the inlet 22 an injection device 6 provided for introducing an additive in an injection direction E.

According to the embodiment according to 1 the additive is from the injection direction E in the channel 20 deflected in the direction of the channel axis K2. The inlet 22 has an inlet cross section E22 in which a static mixing element 3 is arranged and through which the additive is injected through.

According to the embodiment according to 2 the injection direction E and the channel axis K2 are coaxial or at least parallel.

In front and behind the case 11 are a downstream converter housing 4 with a downstream substrate 41 and an upstream converter housing 5 with an upstream substrate 51 arranged. These two cases 4 . 5 are according to 2 in the case 11 , in the entrance opening 12 and in the exit opening 13 plugged in. The substrates 41 . 51 are coaxial with the center input axis M12 of the input port 12 and to the center exit axis M13 of the exit port 13 arranged.

The determination of the necessary length L2 is in the schematic diagram according to 3 clarified. So that the entire exhaust stream or each flow thread after entering the inlet opening 12 can be deflected in the radial direction, the channel wall protrudes 21 of the canal 20 in the radial direction with a dimension beyond the center input axis M12 that is greater than a radius R12 of the input port 12 or a radius R51 of the upstream substrate 51 , Taking into account the angle a with which the channel axis K2 is set in relation to the center output axis M13, the length L2 must be at least greater than the quotient of the mean radius R51 of the substrate 41 to sinus a. Depending on how the diameter of the upstream converter housing 5 to the diameter of the upstream substrate 51 or which design geometry is used, it may be sufficient that the length L2 is greater than the quotient of the mean radius R12 of the input opening 12 to sinus a.

In 4 is the section AA 'according to 2 represented, after which the curved channel wall 21 shown in the direction of the center output axis M13 the outlet 23 closes over its entire outlet cross-section A23. The radius of the outlet section A23 in this case corresponds both to a radius R41 of the downstream substrate 41 as well as the radius R51 of the upstream substrate 51 ,

In 5 an embodiment is shown, in which in the channel 20 after the entrance opening 12 a mixing element 3 is arranged. The entrance opening 12 is formed like a grid, wherein portions of the channel wall 21 are bent in the radial direction as a flap wing-like inward or outward.

To 6 is the channel 20 in the area of the entrance opening 12 conical. To 7 Instead of a lattice-like structure, a perforation P is provided, which forms a corresponding flow cross-section S12 in the sum as well as the grid-like structure.

To 8th are the two substrates 41 . 51 arranged axially parallel so that the center input axis M12 and the center output axis M13 are arranged in parallel.

To 9 the two substrate central axes are arranged at an angle b of 30 ° to each other. The angle b can vary between 0 ° and 180 °. 0 ° corresponds to the embodiment according to 1 and 2 , 180 ° corresponds to the embodiment according to 10 ,

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 112010002589 T5 [0002]

Claims (15)

Mixing chamber ( 1 ) for mixing an additive in an exhaust system of an internal combustion engine a) with a one-part or multi-part housing ( 11 ), which has an entrance opening ( 12 ) for exhaust gas with a flow cross section (S12) and with a central input axis (M12) and a downstream of the inlet opening ( 12 ) arranged exit opening ( 13 ) for exhaust gas having a flow cross-section (S13) and having a central output axis (M13), wherein b) within the housing ( 11 ) a flow guide ( 2 ) between the two openings ( 12 . 13 ), characterized in that c) the flow guide element ( 2 ) is tubular and has at least one channel (K2) having a channel ( 20 ) with an inlet ( 22 ) and with an outlet ( 23 ), over which the entire exhaust gas flow in a direction parallel to the channel axis (K2) flow direction (S) to the output port ( 13 ), wherein d) the flow direction (S) deviates relative to the central exit axis (M13) by an angle a between 20 ° and 80 °. Mixing chamber ( 1 ) according to claim 1, characterized in that the outlet ( 23 ) has a right angle to the central exit axis (M13) extending outlet cross-section (A23), wherein the outlet cross section (A23) is at most 20% larger or smaller than the flow cross-section (S13) of the outlet opening (A13) 13 ) and / or the channel axis (K2) intersects the central exit axis (M13) at an angle a between 20 ° and 80 °. Mixing chamber ( 1 ) according to claim 2, characterized in that the flow guide ( 2 ) in the direction of the channel axis (K2) the outlet ( 23 ) Opposite upstream of an inlet ( 22 ) having an inlet area (E22) whose size is reduced by 10% to 70% from the outlet area (A23). Mixing chamber ( 1 ) according to one of the preceding claims, characterized in that the channel ( 20 ) of a channel wall ( 21 ) is encased and the channel wall ( 21 ) is closed or formed perforation-free. Mixing chamber ( 1 ) according to one of the preceding claims, characterized in that the channel ( 2 ) along the channel axis (K2), starting at the central exit axis (M13), has a length (L2) which is at least equal to the quotient of a mean radius (R12) of the entry opening (L2). 12 ) corresponds to sine a, ie L2 ≥ ^R12 / _sina . Mixing chamber ( 1 ) according to one of the preceding claims, characterized in that upstream of the inlet opening ( 12 ) a substrate ( 51 ) and the channel ( 2 ) along the channel axis (K2) starting at the central exit axis (M13) has a length (L2) which is at least equal to the quotient of a mean radius (R51) of a substrate ( 41 ) corresponds to sine a, ie L2 ≥ ^R51 / _sina . Mixing chamber ( 1 ) according to one of the preceding claims, characterized in that the housing ( 11 ) an over the flow cross section (S12, S13) in the radial direction to the central input axis (M12) protruding dome ( 14 ), which at least partially covers the channel ( 2 ) or at least partially the channel ( 2 ) protrudes. Mixing chamber ( 1 ) according to one of the preceding claims, characterized in that on the channel ( 2 ) to the inlet ( 22 ) subsequently and / or in the channel ( 2 ) one or more mixing elements ( 3 ) for mixing into the mixing chamber ( 1 ) injected additive are arranged. Mixing chamber ( 1 ) according to one of the preceding claims, characterized in that at the cathedral ( 14 ) or on the flow guide ( 2 ) an injection device ( 6 ) is arranged, which the additive in an injection direction (E) in the flow guide ( 2 ), wherein the injection direction (E) by up to 90 ° to the channel axis (K2) is employed. Mixing chamber ( 1 ) according to one of the preceding claims, characterized in that to the output opening ( 13 ) then a downstream converter housing ( 4 ) with a downstream substrate ( 41 ), wherein the downstream substrate ( 41 ) with the outlet ( 23 ) is fluidically connected. Mixing chamber ( 1 ) according to one of the preceding claims, characterized in that in front of the inlet opening ( 12 ) an upstream converter housing ( 5 ) with the upstream substrate ( 51 ), wherein the upstream substrate ( 51 ) with the inlet ( 22 ) is fluidically connected. Mixing chamber ( 1 ) according to one of the preceding claims, characterized in that the center input axis (M12) and the center output axis (M13) are arranged parallel or coaxial or intersect at an angle between 10 ° and 80 °. Mixing chamber ( 1 ) according to one of the preceding claims, characterized in that the input opening ( 12 ) and the exit opening ( 13 ) in the direction of the center input axis (M12) one behind the other or in the radial direction to the central input axis (M12) are arranged side by side. System consisting of a mixing chamber ( 1 ) according to one of the preceding claims and an exhaust system for an internal combustion engine. Method of flowing from a substrate ( 41 ) with a channel structure which is aligned in the direction of the central exit axis (M13), with a mixed flow of exhaust gas and an additive, characterized in that the total flow in parallel, by a maximum of 5 ° from a mean, straight flow direction (S) different Flow directions directly onto the substrate ( 41 ), wherein the flow direction (S) is inclined by an angle a between 20 ° and 80 ° with respect to the center output axis (M13).

Images