Exhaust gas-treating device

Abstract

An exhaust gas-treating device (1) for an exhaust system of an internal combustion engine, especially of a motor vehicle, has a housing (2), which has a jacket (3) extending circumferentially on the side and two end-side end bottoms (4, 5). Maintenance is simplified with at least one mounting tube (6), which passes through one or the first end bottom (4) and into the outlet end (8) of which a particle filter (7) is plugged axially from the outside, with a deflecting housing (9). The deflecting housing (9) contains a deflecting chamber (10), and has at least one inlet (11) communicating with the deflecting chamber (10) and at least one outlet (12) communicating with the deflecting chamber (10). A fastening device (13) is provided for detachably fastening the respective inlet (11) at the respective outlet end (8) of the mounting tube (6).

Claims

1. A particle filter comprising: a tubular jacket; and a filter element disposed inside the jacket, the jacket extending around a side surface of the filter element, the jacket having a jacket inlet at a jacket inlet end, a jacket outlet at a jacket outlet end of the jacket, and a jacket side surface axially between the jacket inlet end and the jacket outlet end, the jacket inlet end and the jacket outlet end being disposed at opposite axial ends of the jacket, the jacket having a single axially fixating collar that projects radially outwardly from the jacket side surface, wherein the single axially fixating collar is disposed axially closer to the jacket outlet end than to the jacket inlet end, wherein the jacket is configured such that the jacket inlet end is axially inserted into a particle filter mounting tube until the single axially fixating collar axially abuts an edge of the particle filter mounting tube, the single axially fixating collar remaining outside the particle filter mounting tube.

2. The particle filter as set forth in claim 1, wherein the filter element has a filter element inlet end and a filter element outlet end at opposite axial ends of the filter element, and the filter element side surface is disposed axially between the filter element inlet end and the filter element outlet end.

3. The particle filter as set forth in claim 2, wherein the jacket outlet end is disposed axially beyond the filter element outlet end.

4. The particle filter as set forth in claim 1, wherein the jacket side surface is cylindrical between the collar and the jacket inlet end.

5. The particle filter as set forth in claim 1, wherein the jacket side surface is continuous between the collar and the jacket inlet end.

6. The particle filter as set forth in claim 1, further comprising a mounting mat annularly enveloping the filter element between the filter element and the jacket.

7. The particle filter as set forth in claim 1, wherein the collar extends annularly around an entire periphery of the jacket.

8. The particle filter as set forth in claim 1, wherein the collar and the jacket are formed integrally.

9. The particle filter as set forth in claim 1, wherein the collar is disposed at the jacket outlet end.

10. The particle filter as set forth in claim 1, wherein the jacket inlet end is disposed axially beyond the filter element inlet end.

11. The particle filter as set forth in claim 1, wherein the jacket inlet end is even with the filter element inlet end.

12. The particle filter as set forth in claim 1, wherein the jacket inlet faces in an axial direction of the jacket.

13. The particle filter as set forth in claim 1, wherein the jacket outlet faces in an axial direction of the jacket.

14. An exhaust gas treating device comprising: a particle filter mounting tube; and a particle filter removably disposed in the particle filter mounting tube, wherein the particle filter comprises a tubular jacket and a filter element disposed inside the jacket, the jacket extending around a side surface of the filter element, the jacket having a jacket inlet at a jacket inlet end, a jacket outlet at a jacket outlet end of the jacket, and a jacket side surface axially between the jacket inlet end and the jacket outlet end, the jacket inlet end and the jacket outlet end being disposed at opposite axial ends of the jacket, the jacket having a collar that projects radially outwardly from the jacket side surface, the collar being in one piece with the jacket, wherein the particle filter is configured to be axially insertable into the outlet side end of the particle filter mounting tube with the collar axially fastenable to an outlet side end of the particle filter mounting tube so that the outlet side end of the particle filter mounting tube is upstream of the jacket outlet end and at least a portion of the collar is located at a position external to the particle filter mounting tube.

15. The exhaust gas treating device as set forth in claim 14, wherein the particle filter is removably fastenable to the outlet side end of the particle filter mounting tube so that the jacket outlet end faces in a direction opposite of a direction of flow through an outlet of the exhaust gas treating device.

16. The exhaust gas treating device as set forth in claim 14, wherein the particle filter is removably fastenable to the outlet side end of the particle filter mounting tube so that the jacket inlet end faces in a direction perpendicular to a direction of flow through an inlet of the exhaust gas treating device.

17. The exhaust gas treating device as set forth in claim 14, wherein the particle filter is removably fastened to an outlet side end of the particle filter mounting tube so that the collar abuts the outlet side end of the particle filter mounting tube.

18. The exhaust gas treating device as set forth in claim 17, wherein the collar is disposed axially closer to the jacket outlet end than to the jacket inlet end.

19. The exhaust gas treating device as set forth in claim 17, wherein the collar is disposed at the jacket outlet end.

20. The exhaust gas treating device as set forth in claim 14, wherein the exhaust gas treating device comprises a housing, wherein the particle filter mounting tube is fixedly arranged in relation to the housing and wherein an outlet end of the particle filter mounting tube filter extends outside of the housing.

21. The exhaust gas treating device as set forth in claim 20, wherein an outlet side end section of the particle filter extends outside of the outlet end of the particle filter mounting tube.

22. The exhaust gas treating device as set forth in claim 14, wherein the exhaust gas treating device comprises a housing, wherein the outlet side end of the particle filter extends outside of the housing.

23. An exhaust gas treating device comprising: a particle filter mounting tube; and a particle filter removably received in the particle filter mounting tube, wherein the particle filter comprises a tubular jacket and a filter element disposed inside the jacket, the jacket extending around a side surface of the filter element, the jacket having a jacket inlet at a jacket inlet end, a jacket outlet at a jacket outlet end of the jacket, and a jacket side surface axially between the jacket inlet end and the jacket outlet end, the jacket inlet end and the jacket outlet end being disposed at opposite axial ends of the jacket, the jacket having a collar that projects radially outwardly from the jacket side surface, the collar being in one piece with the jacket, wherein the particle filter is configured to be axially insertable in and removable from the outlet side of the particle filter mounting tube and the particle filter is removably axially fastened to an outlet side end of the particle filter mounting tube so that the collar axially abuts the outlet side end of the particle filter mounting tube and at least a portion of the collar is located at a position external to the particle filter mounting tube.

24. The exhaust gas treating device as set forth in claim 23, wherein the collar is disposed axially closer to the jacket outlet end than to the jacket inlet end.

25. The exhaust gas treating device as set forth in claim 23, wherein the collar is disposed at the jacket outlet end.

26. An exhaust gas treating device comprising: first and second chambers for conveying gas flow, the first and second chambers being arranged along spaced parallel axes, wherein a particle filter mounting tube defines the first chamber; a particle filter arranged in the particle filter mounting tube, wherein the particle filter comprises a tubular jacket and a filter element disposed inside the jacket, the jacket extending around a side surface of the filter element, the jacket having a jacket inlet at a jacket inlet end, a jacket outlet at a jacket outlet end of the jacket, and a jacket side surface axially between the jacket inlet end and the jacket outlet end, the jacket inlet end and the jacket outlet end being disposed at opposite axial ends of the jacket, wherein the particle filter is removably fastened to an outlet side end of the particle filter mounting tube via fastening means so that the outlet side end of the particle filter mounting tube is upstream of the jacket outlet end; and a gas deflecting housing configured for conveying a gas flow between the first and second chambers, wherein an inlet of the gas deflecting housing is fastened to the outlet side end of the particle filter mounting tube and to the jacket outlet end via the fastening means.

27. An exhaust gas treating device comprising: first and second chambers for conveying a gas flow, the first and second chambers being arranged along spaced parallel axes, wherein a particle filter mounting tube defines the first chamber; a particle filter, wherein the particle filter comprises a tubular jacket and a filter element disposed inside the jacket, the jacket extending around a side surface of the filter element, the jacket having a jacket inlet at a jacket inlet end, a jacket outlet at a jacket outlet end of the jacket, and a jacket side surface axially between the jacket inlet end and the jacket outlet end, the jacket inlet end and the jacket outlet end being disposed at opposite axial ends of the jacket, the jacket having a collar that projects radially outwardly from the jacket side surface, wherein the particle filter is configured to be axially insertable into the outlet side end of the particle filter mounting tube with the collar fastened to an outlet side end of the particle filter mounting tube via fastening means so that the outlet side end of the particle filter mounting tube is upstream of the collar and such that the collar axially abuts the outlet side end of the particle filter mounting tube; and a gas deflecting housing configured for conveying a gas flow between the first and second chambers, wherein an inlet of the gas deflecting housing is fastened to the outlet side end of the particle filter mounting tube and to the collar via the fastening means.

28. A method for replacement of a particle filter in an exhaust gas treating device, the particle filter comprising a tubular jacket and a filter element disposed inside the jacket, the jacket extending around a side surface of the filter element, the jacket having a jacket inlet at a jacket inlet end, a jacket outlet at a jacket outlet end of the jacket, and a jacket side surface axially between the jacket inlet end and the jacket outlet end, the jacket inlet end and the jacket outlet end being disposed at opposite axial ends of the jacket, the jacket having a collar projecting radially outwardly from the jacket side surface, the method comprising the step of: removably fastening the particle filter to an outlet side end of a particle filter mounting tube of the exhaust gas treating device so that the outlet side end of the particle filter mounting tube is upstream of the jacket outlet end so that the collar axially abuts the outlet side end of the particle filter mounting tube and so that the collar is outside of the particle filter mounting tube.

29. The method as set forth in claim 28, further comprising removably fastening the particle filter to the outlet side end of the particle filter mounting tube of the exhaust gas treating device so that the jacket outlet end faces in a direction opposite of a direction of flow through an outlet of the exhaust gas treating device.

30. The method as set forth in claim 28, further comprising removably fastening the particle filter to the outlet side end of the particle filter mounting tube of the exhaust gas treating device so that the jacket inlet end faces in a direction perpendicular to a direction of flow through an inlet of the exhaust gas treating device.

31. The method as set forth in claim 28, wherein the jacket and the collar form a one-piece structure.

32. The method as set forth in claim 31, wherein the collar is disposed axially closer to the jacket outlet end than to the jacket inlet end.

33. The method as set forth in claim 31, further comprising removably fastening the particle filter to the outlet side end of the particle filter mounting tube of the exhaust gas treating device so that the outlet of the particle filter is outside of the housing.

34. A method for replacement of a particle filter in an exhaust gas treating device, the particle filter comprising a tubular jacket and a filter element disposed inside the jacket, the jacket extending around a side surface of the filter element, the jacket having a jacket inlet at a jacket inlet end, a jacket outlet at a jacket outlet end of the jacket, and a jacket side surface axially between the jacket inlet end and the jacket outlet end, the jacket inlet end and the jacket outlet end being disposed at opposite axial ends of the jacket, the jacket having a collar that projects radially outwardly from the jacket side surface, the collar being in one piece with the jacket, the method comprising the step of: removably fastening the particle filter to an outlet side end of a particle filter mounting tube of the exhaust gas treating device so that the collar axially abuts the outlet side end of the particle filter mounting tube outside of the particle filter mounting tube.

35. The method as set forth in claim 33, further comprising removably fastening the particle filter to the outlet side end of the particle filter mounting tube so that the collar is disposed axially closer to the jacket outlet end than to the jacket inlet end.

36. A method for replacement of a particle filter in an exhaust gas treating device, the exhaust gas treating device having first and second chambers for conveying the gas flow, the first and second chambers being arranged along spaced parallel axes, wherein a particle filter mounting tube defines the first chamber, the particle filter comprising a tubular jacket and a filter element disposed inside the jacket, the jacket extending around a side surface of the filter element, the jacket having a jacket inlet at a jacket inlet end, a jacket outlet at a jacket outlet end of the jacket, and a jacket side surface axially between the jacket inlet end and the jacket outlet end, the jacket inlet end and the jacket outlet end being disposed at opposite axial ends of the jacket, the method comprising the steps of: removably fastening the particle filter to an outlet side end of a particle filter mounting tube of the exhaust gas treating device via fastening means so that the outlet side end of the particle filter mounting tube is upstream of the jacket outlet end; and removably fastening an inlet of a gas deflecting housing configured for conveying a gas flow between the first and second chambers to the outlet side end of the particle filter mounting tube and to the jacket outlet end via the fastening means.

37. A method for replacement of a particle filter in an exhaust gas treating device, the exhaust gas treating device having first and second chambers for conveying the gas flow, the first and second chambers being arranged along spaced parallel axes, wherein a particle filter mounting tube defines the first chamber, the particle filter comprising a tubular jacket and a filter element disposed inside the jacket, the jacket extending around a side surface of the filter element, the jacket having a jacket inlet at a jacket inlet end, a jacket outlet at a jacket outlet end of the jacket, and a jacket side surface axially between the jacket inlet end and the jacket outlet end, the jacket inlet end and the jacket outlet end being disposed at opposite axial ends of the jacket, the jacket having a collar that projects radially outwardly from the jacket side surface, the collar being on one piece with the jacket, the method comprising the steps of: removably fastening the particle filter to an outlet side end of a particle filter mounting tube of the exhaust gas treating device via fastening means so that the outlet side end of the particle filter mounting tube is upstream of the collar and such that the collar axially abuts the particle filter mounting tube; removably fastening the particle filter to the outlet side end of the particle filter mounting tube by fastening the collar with the fastening means; and removably fastening an inlet of a gas deflecting housing configured for conveying a gas flow between the first and second chambers to the outlet side end of the particle filter mounting tube and to the collar via the fastening means.

38. The method as set forth in claim 37, further comprising removably fastening the inlet of the gas deflecting housing to the outlet side end of the particle filter mounting tube by fastening the inlet of the gas deflecting housing to the collar with the fastening means.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) In the drawings:

(2) FIG. 1 is an axial view of an exhaust gas-treating device with deflecting housing;

(3) FIG. 2 is an axial view of a deflecting housing of another embodiment;

(4) FIG. 3 is a longitudinal section of the exhaust gas-treating device corresponding to the section lines III in FIG. 1;

(5) FIG. 4 is an enlarged view of a detail IV in FIG. 3, showing one clamp connection embodiment of the fastening means;

(6) FIG. 5 is an enlarged view of a detail IV in FIG. 3, showing another clamp connection embodiment of the fastening means;

(7) FIG. 6 is an enlarged view of a detail IV in FIG. 3, showing another clamp connection embodiment of the fastening means;

(8) FIG. 7 is an enlarged view of a detail IV in FIG. 3, showing another embodiment of the fastening means;

(9) FIG. 8 is an enlarged view of a detail VIII from FIG. 3, showing an embodiment for providing axial displaceability;

(10) FIG. 9 is an enlarged view of a detail VIII from FIG. 3, showing another embodiment for providing axial displaceability;

(11) FIG. 10 is an enlarged view of a detail VIII from FIG. 3, showing another embodiment for providing axial displaceability;

(12) FIG. 11 is an enlarged view of a detail VIII from FIG. 3, showing another embodiment for providing axial displaceability;

(13) FIG. 12 is an enlarged view of a detail VIII from FIG. 3, showing another embodiment for providing axial displaceability;

(14) FIG. 13 is an enlarged view of a detail VIII from FIG. 3, showing another embodiment for providing axial displaceability;

(15) FIG. 14 is a side view of the exhaust gas-treating device in the area of the deflecting housing according to one embodiment;

(16) FIG. 15 is a side view of the exhaust gas-treating device in the area of the deflecting housing according to another embodiment;

(17) FIG. 16 is a side view of the exhaust gas-treating device in the area of the deflecting housing according to another embodiment;

(18) FIG. 17 is a longitudinal section of the exhaust gas-treating device corresponding to section lines XVII in FIG. 1;

(19) FIG. 18 is a sectional view as in FIG. 17, but showing a different embodiment of a mixing housing;

(20) FIG. 19 is a sectional view as in FIG. 17, but showing another different embodiment of the mixing housing;

(21) FIG. 20 is a sectional view as in FIG. 17, but showing another different embodiment of the mixing housing;

(22) FIG. 21 is a sectional view as in FIG. 17, but showing another different embodiment of the mixing housing;

(23) FIG. 22 is a sectional view as in FIG. 17, but showing another different embodiment of the mixing housing;

(24) FIG. 23 is a sectional view as in FIG. 17, but showing another different embodiment of the mixing housing;

(25) FIG. 24 is an axial view of the mixing housing corresponding to the embodiment according to FIG. 18;

(26) FIG. 25 is an axial view of the mixing housing corresponding to the embodiment according to FIG. 19;

(27) FIG. 26 is an axial view of the mixing housing corresponding to the embodiment according to FIG. 20;

(28) FIG. 27 is an axial view of the mixing housing corresponding to the embodiment according to FIG. 21;

(29) FIG. 28 is an axial view of the mixing housing corresponding to the embodiment according to FIG. 22;

(30) FIG. 29 is an axial view of the mixing housing corresponding to the embodiment according to FIG. 23; and

(31) FIG. 30 is another sectional view as in FIGS. 17-23 for illustrating various installation positions of a dosing means.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

(32) Referring to the drawings in particular, corresponding to FIG. 1, an exhaust gas-treating device 1, which is intended for use in an exhaust system of an internal combustion engine, especially of a motor vehicle, may have a housing, which has a jacket 3 extending laterally circumferentially, as well as two end-side bottoms or end bottoms 4, 5, of which only one or the first end bottom 4 faces the viewer in FIG. 1. The other or second end bottom 5 is arranged at the end of the housing 2 located away from the first end bottom 4.

(33) Corresponding to FIGS. 1-3, the exhaust gas-treating device 1 is preferably equipped with at least one mounting tube 6. Precisely one such mounting tube 6 is provided in the embodiment shown in FIGS. 1 and 3. FIG. 2 shows, purely as an example, an embodiment with two such mounting tubes 6. The respective mounting tube 6 passes axially through the first end bottom 4. Furthermore, the respective mounting tube 6 accommodates a particle filter 7. The respective particle filter 7 is plugged for this into an outlet end 8 of the mounting tube 6, which said outlet end 8 passes through the first end bottom 4, axially and from the outside, i.e., from a side facing away from the interior space 23 of housing 2. Particle filter 7 is arranged now coaxially with the mounting tube 6.

(34) In addition, a deflecting housing 9 is provided in the example. This contains, corresponding to FIG. 3, a deflecting chamber 10. Furthermore, the deflecting housing 9 has at least one inlet 11 communicating with the deflecting chamber 10 as well as at least one outlet 12 communicating with the deflecting chamber 10. The deflecting housing 9 is attached to the housing 2 of the exhaust gas-treating device 1, which can hereinafter also be called main housing 2. At least one fastening means 13, which makes possible the detachable fastening of the respective inlet 11 of the deflecting housing 9 to the respective outlet end 8 of the respective mounting tube 6, is used for this.

(35) In addition or as an alternative, the exhaust gas-treating device 1 being shown here may also have, besides, a mixing housing 14, which is arranged in the main housing 2. Mixing housing 14 contains a mixing chamber 15 and has an inlet 16, which communicates with the mixing chamber 15, as well as an outlet 17, which likewise communicates with the mixing chamber 15. Both the inlet 16 and the outlet 17 pass through the first end bottom 4 of the main housing 2. The mixing chamber 14 is recognizable in the embodiments being shown here in the area of a front side 18 facing the first bottom 4 only in physical contact with the main housing 2, whereas it is otherwise located at a spaced location from the main housing 2, i.e., especially from jacket 3 and from the second end bottom 5. The dimensioning of the mixing housing 14 is preferably adapted to the dimensioning of the main housing 2 such that a deflection area 19 located away from the inlet 16 in the mixing chamber 15 is located farther away from the first end bottom 4 than from the second end bottom 5. In other words, the mixing housing 14 extends from the first end bottom 4 to the second end bottom 5, but preferably without touching this. As a result, mixing chamber 15 assumes a comparatively great length in the axial direction of the especially cylindrical or barrel-shaped main housing 2.

(36) Outlet 17 of the mixing housing 14 opens into a deflecting chamber 20, which can hereinafter be called an additional deflecting chamber 20. Furthermore, at least one inlet 21 of at least one SCR catalytic converter 22 opens into this additional deflecting chamber 20. The respective inlet 21 of the SCR catalytic converter 22 likewise passes through the first end bottom 4. The respective SCR catalytic converter 22 extends otherwise in the interior 23 of the main housing 2. Corresponding to FIG. 1, the exhaust gas-treating device 1 has two such SCR catalytic converters 22 in this example. It is clear that there may also be more or fewer SCR catalytic converters 22. Gas flows through the two SCR catalytic converters 22 in parallel and they open on the outlet side, via a corresponding outlet 24 each, into the interior 23 or into a settling chamber 25 of the main housing 2, which said chamber is formed in the interior 23. Purely as an example, the SCR catalytic converter 22 has two SCR catalytic converters 26 in the example, which are arranged one after the other, i.e., gas can flow through them in series.

(37) Main housing 2 has, in the usual manner, an outlet port 27, which communicates, for example, with the settling chamber 25. In addition, an intermediate bottom 28, which separates in the interior 23 the settling chamber 25 from an absorption chamber 29, which may be filled with a sound-absorbing material 30 in the example, may be arranged in the main housing 2. Intermediate bottom 28 is designed such that it is permeable to air-borne sound. For example, it has a corresponding perforation. In addition, additional sound-absorbing measures may be provided in the exhaust gas-treating device 1.

(38) Main housing 2 is equipped, furthermore, with an inlet port 31, which is connected corresponding to FIG. 3 in the interior 23 via a deflecting shell 32 to an inlet 33 of an oxidation-type catalytic converter 34. The oxidation-type catalytic converter 34 is arranged upstream of the particle filter 7. If a plurality of particle filters 7 are accommodated in the main housing 2, correspondingly many oxidation-type catalytic converters 34 are provided as well, to which exhaust gas is admitted via a common inlet port 31 or via separate inlet ports 31. It is likewise possible to provide a common oxidation-type catalytic converter 34 for a plurality of particle filters 7.

(39) A preferred embodiment and corresponding processes will be discussed in more detail below with respect to FIGS. 4-7. The particle filter 7 correspondingly has an outlet-side end section 35, which faces the deflecting housing 9 and is preferably configured such that it can be integrated into the fastening means 13. The end section 35 is integrated in the fastening means 13 such that axial fixation of the particle filter 7 to the mounting tube 6 or to the inlet 11 of the deflecting housing 9 and hence also axial fixation of the particle filter 7 to the deflecting housing 9 is also formed hereby. By separating the fastening means 13, the axial fixation of the particle filter 7 is eliminated as well, so that the particle filter 7 can be pulled axially out of the mounting tube 6 when the deflecting housing 9 is removed. By mounting the deflecting housing 9 and by fastening the deflecting housing 9 to the main housing 2, the respective particle filter 7 is also fixed at the same time in the relative position intended therefor by means of the fastening means 13.

(40) The fastening means 13 is designed as a clamp connection in the embodiments according to FIGS. 4-6. Contrary to this, FIG. 7 shows a fastening means 13 designed as a screwed flange connection. Corresponding to FIGS. 4-7, the respective fastening means 13 comprises a first mounting flange 36, which is formed at the free end of the respective inlet 11. Furthermore, the fastening means 13 comprises a second mounting flange 37, which is formed at the free outlet end 8 of the respective mounting tube 6. The outlet-side end section 35 of the particle filter 7 has a collar 38, which projects outwardly and extends circumferentially in some segments or preferably in its entirety. In the mounted state shown, this collar 38 is arranged axially between the mounting flanges 36, 37 of the fastening means 13. The fastening means 13 is preferably configured now such that it makes it possible to axially brace the collar 38 between the mounting flanges 36, 37.

(41) The respective fastening means 13 may be equipped with at least one seal 39 in order to improve the gas tightness of the connection made. Exactly one such seal 39, which is axially directly in contact with the two mounting flanges 36, 37, is provided in the example according to FIGS. 4 and 7. The collar 38 is directly in contact with the mounting flanges 36, 37 in these cases. Contrary to this, two such seals 39 are provided in the embodiments according to FIGS. 5 and 6, and the mounting flanges 36, 37 are supported at the collar 38 via one of these seals 39 on sides mutually facing away from one another. Especially advantageous is an embodiment in which the seals 39 are fastened to the collar 38, e.g., by bonding or vulcanization. The respective seal 39 can then also be replaced automatically by changing the particle filter 7. In addition, mounting becomes simpler.

(42) To make it possible to replace the particle filter 7 in a simplified manner, it is preferably equipped with a jacket 41, which has a tubular design and which accommodates at least one particle filter element 42. The particle filter element 42 is enveloped here by means of a mounting mat 43 in the usual manner and is thus positioned in the jacket 41. The aforementioned collar 38 is preferably made integrally in one piece with this jacket 41 of the particle filter 7.

(43) Corresponding to FIG. 3, an inlet-side end section 40 of the particle filter 7, which end section is located away from the deflecting housing 9, can be radially supported at the mounting tube 6 such that the end section 40 is axially displaceable relative to the mounting tube 6. This axial displaceability of the inlet-side end section 40 can be embodied in different ways. A plurality of alternative solutions are shown as examples in FIGS. 8-13. For example, an annular or ring segment-shaped bearing body 44, which can slide on the mounting tube 6, may be fastened to the particle filter 7 or to the jacket 41 thereof corresponding to FIG. 8.

(44) Corresponding to FIGS. 9 and 12, the bearing body 44 may be made elastic and formed, for example, by a collar or pad or wiremesh or mounting mat material, which extents fully circumferentially or extends circumferentially in some segments. This elastic bearing body 44 may be fastened to the particle filter 7 or the jacket 41 thereof corresponding to FIG. 9 and slide on the mounting tube 6. It is likewise possible, corresponding to FIG. 12, to arrange such an elastic bearing body 44 at the mounting tube 6, so that the particle filter 7 or the jacket 41 thereof can slide thereon.

(45) No separate bearing body 14 is used in the embodiments according to FIGS. 10, 11 and 13, but a contour that makes mounting possible is formed directly at the particle filter 7 or at the jacket 41 thereof corresponding to FIG. 10 or directly at the mounting tube 6 corresponding to FIGS. 11 and 13. For example, FIG. 10 shows a cross-section expansion 45, which is formed directly at jacket 41 of particle filter 7 and which may be configured such that it extends fully circumferentially or extends circumferentially in some segments. As can be recognized, this cross-section expansion 45 is supported directly at the mounting tube 6. Contrary to this, a cross-section contraction 46 formed at the mounting tube 6, which is dimensioned such that it comes into direct radial contact with the particle filter 7 or with the jacket 41 thereof, is provided in the embodiments according to FIGS. 11 and 13. This cross section contraction 46 may also extend fully circumferentially or extend circumferentially in some sections. For example, the linear support shown in FIG. 11 indicates a cross section contraction 46 extending in an annular pattern, while the flat support shown in FIG. 13 indicates a cross section contraction 46 extending circumferentially in a punctiform manner or in some segments, which has a plurality of contact areas arranged at spaced locations from one another in the circumferential direction.

(46) FIG. 3 shows another peculiarity of the exhaust gas-treating device 1 shown here. The oxidation-type catalytic converter 34 comprises in the example an oxidation-type catalytic converter element 47, which is arranged in a tubular jacket 48 and is positioned in the corresponding jacket 48 by means of a corresponding mounting mat 49. Jacket 48 of the oxidation-type catalytic converter 34 is axially extended on an outlet side 50 of the oxidation-type catalytic converter 34. This axial outlet-side extension of jacket 48 of the oxidation-type catalytic converter 34 forms the mounting tube 6 in the embodiments being shown here. An extreme simplification and weight reduction is obtained hereby and simple possibility of replacing the particle filter 7 is achieved.

(47) Corresponding to FIG. 3, the outlet 12 of the deflecting housing 9 and the inlet 16 of the mixing housing 14 are connected to one another in a communicating manner. A fastening means 51, which makes it possible to detachably fasten the outlet 12 and the inlet 16 to one another, shall be used for this connection as well. This additional fastening means 51 may be, in principle, of the same design as the aforementioned fastening means 13. Thus, this is preferably also a clamp connection or a screwed flange connection.

(48) FIGS. 14-16 show different embodiments. FIGS. 14 and 15 show a clamp connection each, wherein the respective clamp 52 is designed as a flat clamp 52, which brings about only radial pressing of the tube sections plugged coaxially into one another, namely, between the outlet 8 of the mounting tube 6 and the inlet 11 of the deflecting housing 9, on the one hand, and between the outlet 12 of the deflecting housing 9 and the inlet 16 of the mixing housing 14, on the other hand. An embodiment corresponding to FIG. 15, in which the respective clamp connection 13, 51 is designed as a V clamp 53, is preferred. Such a V clamp 53 can be equipped corresponding to FIGS. 4-6 with a circumferential tensioning band 54 as well as with a V-section 55, as a result of which axial pressing of the mounting flanges 36, 37 can be achieved by means of such a V clamp 53, which can also be called a V-band clamp. FIG. 15 indicates tightening means 56, which make it possible to tighten the respective clamp 53 in the usual manner. Contrary to this, FIG. 14 shows for the respective clamp 52 only an area 57, which is intended for arranging a suitable tightening means.

(49) Finally, FIG. 16 shows an embodiment in which the respective fastening means 13, 51 is designed as a screwed flange connection 58. Corresponding screws 59 can be recognized in FIG. 7. It can be determined from FIGS. 14-16 that the fastening means 13, 51 operating with V-clamps 53 have an especially compact design in the axial direction. FIG. 3 indicates that the two fastening means 13, 51 do not necessarily have to be of identical design. Thus, the fastening means 13 associated with the particle filter 7 is designed as a V-clamp 53, whereas the fastening means 51 associated with the mixing housing 14 is designed as a flat clamp 52 here as an example.

(50) Corresponding to FIGS. 17-23 and partly corresponding to FIGS. 24-29, at least one guide wall 60 may be arranged in the mixing housing 14. The embodiments according to FIGS. 17 and 20-23 show only a single guide wall 60 each, whereas the embodiments according to FIGS. 18 and 19 additionally have another guide wall 61. The respective guide wall 60, 61 forms within the mixing chamber 15 a mixing section 62, which is indicated by arrows in FIGS. 17-23. However, simple embodiments which make do without a guide wall 60, 61 are conceivable as well.

(51) In addition, an intermediate wall 63, which can be better recognized in the corresponding side views in FIGS. 24 and 25, respectively, is arranged in the mixing housing 14 in the embodiments according to FIGS. 18 and 19. The respective intermediate wall 63 separates two planes within the chamber 15. The mixing section 62 extends through both planes. A section of the mixing section 62, which extends in the plane facing away from the viewer, is indicated for illustration by arrows drawn in broken line, while a section of the mixing section 62, which is located in the plane facing the viewer, is indicated by arrows drawn in solid line. As can be recognized, comparatively complex mixing sections 62 can be embodied. In any case, the exhaust gas flow is passed through the mixing housing 14 such that at least one deflection of 180 becomes established between a flow direction at the inlet 16 and a flow direction at the outlet 17. Even a flow deflection by more than 180 is readily achieved in the embodiments according to FIGS. 18 and 19. The exhaust gas flow is deflected by 180 three times i.e., by a total of about 540, in the embodiment according to FIG. 18. Flow deflection by at least 360 or at least 450 is achieved in the embodiment according to FIG. 19.

(52) The configuration shown in FIG. 20, which makes do without an intermediate wall 63, also leads to a flow deflection by about 540.

(53) The intermediate wall 63 shown in the embodiments according to FIGS. 18 and 19 has at least one passage opening 64, through which the exhaust gas proceeds from one plane to the other plane along the mixing section 62. The mixing housing 14 is preferably designed here such that inlet 16 communicates with one plane while the outlet 17 is communicatingly connected to the other plane. The two guide walls 60, 61 are equipped with a respective connection opening 65 and 66 in the embodiment shown in FIG. 19. The guide walls 60, 61 are arranged in these embodiments within the mixing chamber 15 such that they divide the mixing section 62 into a plurality of sectors. The aforementioned connection openings 65, 66 now make possible a communicating connection of consecutive sectors. The flow guiding can be improved hereby and the mixing section 62 can be extended with simple means. It is clear that the mixing chamber 14 can also make do without a guide wall 60, 61 and without an intermediate wall 63 in a simple embodiment.

(54) The mixing housing 14 is made gas-tight against the interior space 23 of the main housing 2. The main housing 2 can consequently be made of less expensive materials. Furthermore, leakage can be tolerated in the main housing 2, so that the manufacture of the main housing 2 can also be carried out at a lower cost.

(55) In the embodiments being shown here the mixing housing 14 has a housing body 67. Housing body 67 has a front side 18, already mentioned above, which faces the first end bottom 4 of the main housing 2. This front side 18 has the inlet 16 and the outlet 17 of the mixing housing 14. Corresponding to the preferred embodiments being shown here, inlet 16 is designed as an inlet pipe connection, which passes through an inlet opening, not designated more specifically, of the first end bottom 4 of the main housing 2. The inlet opening may be provided as an example with an outwardly projecting collar extending circumferentially in an annular pattern. Analogously hereto, outlet 17 may be designed as an outlet pipe connection, which passes through an outlet opening, not designated more specifically, of the first end bottom 4 of the main housing 2. This outlet opening may also be provided with an outwardly projecting collar extending circumferentially in an annular pattern. The pipe connections preferably extend in parallel to one another.

(56) The housing body 67 may preferably be designed as a monocoque construction and have an upper shell 68 and a lower shell 69 according to the views in FIGS. 24-29. Furthermore, a front shell 70 forming the front side 18 may be provided as an additional component. The mixing housing 14 can be manufactured and made gas-tight at an especially low cost due to the mode of construction being proposed.

(57) The exhaust gas-treating device 1 shown here is equipped corresponding to FIGS. 17-23 as well as 24-29 with at least one dosing means 71, by means of which a liquid educt, namely, preferably a reducing agent, can be introduced into the mixing chamber 15. For example, ammonia or urea or an aqueous urea solution can be mixed with the exhaust gas flow upstream of the SCR catalytic converter 22. The dosing means 71 is preferably positioned for this such that the reducing agent is introduced quasi at the beginning of the mixing section 62. The dosing means 71 is preferably positioned such that it can introduce the reducing agent into the mixing chamber 15 in the area of the inlet 16 of the mixing housing 14. The dosing means 71 is preferably arranged at the first end bottom 4, namely, such that it passes through this first end bottom 4 as well as the mixing housing 14. The dosing means 71 is positioned in the example such that it passes through the front side 18 or the front shell 70 of the housing body 68.

(58) Basically, the arrangement or positioning of the dosing means 71 in relation to the mixing housing 14 can be selected quasi as desired. FIG. 30 therefore shows as an example additional positions, which are suitable for the arrangement of such a dosing means.

(59) To embody the additional deflecting chamber 20, a deflecting shell 72 may be arranged at the first end bottom 4. Together with an area of the first end bottom 4 covered by the deflecting shell 72, the deflecting shell 72 defines the additional deflecting chamber 20. Corresponding to FIG. 1, this deflecting shell 72 is dimensioned such that it covers the outlet 17 of the mixing housing 14 as well as the respective inlet 21 of the respective SCR catalytic converter 22.

(60) Deflecting shell 72 has a double-walled design in the example, which can be used to embody an air gap insulation. A thermally insulating material 73 may likewise be introduced into the double wall of the deflecting shell 72. Jacket 3 of the main housing 2 may be of a double-walled design. This can be used to embody an air gap insulation or to introduce a thermally insulating material 74. The second end bottom 5 may of a double-walled design for an air gap insulation or for receiving a thermally insulating material 75.

(61) Corresponding to FIG. 3, the deflecting housing 9 comprises a pot-shaped shell body 76 and a cover or bottom 77, between which the deflecting chamber 10 is defined. The cover or bottom 77 has the respective inlet 11 and the respective outlet 12. Shell body 76 is of as double-walled design in the example shown in FIG. 3 and may correspondingly form an air gap insulation or, like here, a mounting space for accommodating a thermally insulating material 78.

(62) Corresponding to FIG. 3, as well as corresponding to FIGS. 24-29, a dosing means 79 or an additional dosing means 79, by means of which a liquid educt, especially a reducing agent, can be likewise introduced into the exhaust gas flow, may be provided as an alternative or in addition to the aforementioned dosing means 71. This additional dosing means is arranged at the deflecting housing 9 here, namely, such that it can introduce the corresponding educt in the direction of the inlet 16 of mixing housing 14. The dosing means 79 belongs in this case to the construction volume of the deflecting housing 9. The path to the inlet 16 or through the inlet 16 to the mixing section 15 or to the mixing section 62 is additionally added in this configuration in order to further extend this.

(63) While specific embodiments of the invention have been described in detail to illustrate the application of the principles of the invention, it will be understood that the invention may be embodied otherwise without departing from such principles.