EP3168437A1 - Silencer for an exhaust system - Google Patents

Abstract

The invention relates to a silencer (1) for an exhaust system of an internal combustion engine, preferably a road vehicle, having a housing (2) in which an expansion chamber (6) is formed, with an inlet pipe (7) leading into the housing (2) ) having in the housing (2) an end portion (8) in the expansion chamber (6) has an outlet opening (9), with an exhaust gas from the housing (2) out leading main outlet pipe (10), and with an exhaust gas the secondary housing (15) leading out of the housing (2), which has an inlet opening (16) in the expansion chamber (6). An improved acoustic feedback results when the main outlet pipe (10) in the housing (2) has an initial portion (11) which projects into the end portion (8) of the inlet pipe (7) and if in an overlapping area (13) between the end portion (8) of the inlet pipe (7) and the starting portion (11) of the main outlet pipe (10), a gap (14) is formed in the end portion (8) of the inlet pipe (7) bypassing the starting portion (11) of the main outlet pipe (10) Bypass forms, can flow through the exhaust gas from the inlet pipe (7) in the expansion chamber (6).

Description

The present invention relates to a silencer for an exhaust system of an internal combustion engine, preferably a road vehicle, in particular a passenger car. The invention also relates to a designed with such a muffler exhaust system for an internal combustion engine.

In sports passenger cars, especially sports cars, there is often the need to obtain an acoustic feedback of the current operating state of the vehicle or the internal combustion engine. This need exists especially during acceleration processes, ie at the upper part loads and at full load of the internal combustion engine. In these operating conditions, therefore, a comparatively low sound attenuation is desired. At the same time the lowest possible exhaust back pressure in the muffler for the exhaust gas flow is desired for these operating conditions in order to retrieve as much power to the internal combustion engine for the propulsion of the vehicle can. In contrast, there is the need to achieve the most efficient acoustic damping at low partial load of the internal combustion engine, especially at idle. Since there is a lot of surplus power in this operating range of the internal combustion engine, a relatively high backpressure in the silencer can be accepted for this.

In order for a muffler to be able to meet these opposite requirements, it is possible to realize two exhaust paths in the muffler, one of which can be controlled by means of a control device, while the other is generally uncontrolled. At full load, the controllable exhaust path is opened, whereby the exhaust back pressure is reduced. With appropriate guidance this Controlled exhaust path can also be realized by a reduced sound attenuation. At low power, however, the controllable exhaust path is blocked, so that the exhaust flows only through the uncontrolled path and is efficiently attenuated therein. The problem with such systems, however, is that even at full load, a comparatively efficient acoustic coupling of the controllable, open exhaust path with the acoustic damping means of the muffler is given, so that even at full load, a certain sound attenuation is realized.

The present invention addresses the problem of providing a muffler of the type described above, an improved embodiment, which is characterized in particular by the fact that an acoustic coupling of a full load active exhaust path is reduced with soundproofing means of the muffler.

This problem is solved according to the invention by the subject matter of the independent claim. Advantageous embodiments are the subject of the dependent claims.

The invention is based on the general idea of forming an overlap region between an inlet tube and a main outlet tube, in which inlet tube and main outlet tube are inserted into one another such that a bypass forms in this overlap region between inlet tube and outlet tube, through the exhaust gas from the inlet tube past the main outlet tube can flow into an expansion chamber. In this expansion chamber also opens a Nebenauslassrohr through which exhaust gas can flow out of the expansion chamber. By means of the pipe-in-pipe arrangement proposed according to the invention, it is achieved that the inlet pipe and the main outlet pipe act for a part of the exhaust gas flow, more or less like a continuous exhaust pipe, which is largely decoupled from the silencer of the silencer, whereby for this part of the exhaust gas flow a low sound attenuation and a low exhaust back pressure can be realized. By contrast, the remaining exhaust gas flow flows through the bypass into the expansion chamber and out of the silencer through the secondary outlet pipe. With the help of the expansion chamber is doing an efficient sound attenuation for this part of the exhaust gas flow.

An expansion chamber is generally characterized by a free space in which airborne sound can spread. In principle, sound absorption material may also be arranged in an expansion chamber, as in an absorption chamber, but such an expansion chamber is not completely filled with sound-absorbing material, rather a free space must remain within the expansion chamber, into the airborne sound, e.g. through the bypass or through a perforation, into it can expand.

Furthermore, it has been found that with the aid of such an overlapping region in which a starting region of the main outlet tube projects into an end region of the inlet tube, use of the main outlet tube as a resonance tube, for example in the form of a λ / 4 tube or a λ / 2 tube, is improved, since in the overlap region a particularly efficient vibration excitation can be realized. In this case, the main outlet pipe can be selectively introduced so deeply into the inlet pipe until an optimal vibration excitation in the main outlet pipe is established.

According to an advantageous embodiment, the end portion of the inlet pipe and the initial portion of the main outlet pipe may be configured rectilinear. An axial length of the overlap region with which the main outlet pipe protrudes into the inlet pipe may expediently be twice as large and in particular at least three times as large or at least four times as large such as a diameter of the end portion of the inlet pipe. As a result, in a radially formed between the end portion of the inlet pipe and the starting portion of the Hauptauslassrohrs formed gap which forms the aforementioned bypass, a predetermined flow is realized, for example, has a predetermined flow resistance.

According to a particularly advantageous embodiment, the flow-through cross sections and / or the flow resistances of the main outlet pipe, secondary outlet pipe and gap can be matched to one another such that the exhaust gas flow supplied via the inlet pipe is discharged to the extent of 40% to 60% through the main outlet pipe. Preferably, a flow split of about 50:50 on the Hauptauslassrohr and the Nebenauslassrohr. It has been found that with such a flow distribution, for example, a control device for controlling the flow through the main outlet pipe can be dispensed with. Accordingly, reduces the cost of producing such a muffler. In this case, the main outlet pipe and the auxiliary outlet pipe are uncontrolled and exhaust gas continuously flows through the muffler during operation.

In another advantageous embodiment, it may be provided that in the overlapping region, a cross-section of the gap through which the flow-through is on average approximately the same size as a cross-section through which the main outlet pipe can flow. In the case of a homogeneous flow in the inlet pipe upstream of the overlapping region, with such a ratio of the flow-through cross sections of main outlet pipe and gap, an approximately half-division of the exhaust gas flow onto the main outlet pipe and the auxiliary outlet pipe results.

In another advantageous embodiment, the housing may be cylindrical and equipped with a jacket and with two end floors be. The inlet tube is suitably passed through the jacket. The Hauptauslassrohr is suitably passed through the one end floor. The Nebenauslassrohr is suitably passed through the other end floor. In this way, the muffler can be realized in particular as a transverse muffler, which is arranged in the installed state with respect to its longitudinal central axis transverse to a vehicle longitudinal axis. The outlet pipes emerging from the housing at opposite axial ends can thereby form two end pipes of the exhaust system or lead to two tail pipes. Alternatively, it can also be provided to lead the main outlet pipe and the secondary outlet pipe out of the housing through the same end floor. It is also conceivable to realize the housing in shell construction.

Appropriately, it may be provided that the inlet tube is imperforate. As a result, an efficient flow guidance to the main outlet pipe is realized. Additionally or alternatively, the main outlet tube may be imperforate. This measure also leads to an efficient flow guidance within the main outlet tube. Additionally or alternatively, the secondary outlet tube may be imperforate. This measure ultimately results in that the flow guidance in the secondary outlet pipe is particularly efficient. If all three above-mentioned tubes are imperforate in the housing, the housing expediently contains only the expansion chamber.

In another embodiment, the main outlet tube may have a perforation in the expansion chamber. This ensures that in the exhaust gas entrained airborne sound can escape through the perforation of the Hauptauslassrohrs in the expansion chamber, whereby a certain damping can be realized. Additionally or alternatively, the inlet tube may have a perforation in the overlapping area, thereby providing an acoustic coupling to a space enveloping the overlapping area. In another advantageous embodiment, at least one further chamber may be formed in the housing. The inlet tube and / or the Nebenauslassrohr may have at least in such a further chamber a perforation. As a result, the respective further chamber is acoustically connected via the respective perforation and can serve to dampen the entrained airborne sound. For example, the inlet tube may have a perforation in the overlapping area.

According to a particularly advantageous embodiment, two further chambers may be formed in the housing, namely a first further chamber axially adjacent to the expansion chamber, and a second further chamber axially adjacent to the first further chamber at a side remote from the expansion chamber. Advantageously, it can now be provided that the secondary outlet pipe has a perforation in the second further chamber. As a result, the second further chamber is acoustically coupled via the perforation of the Nebenauslassrohrs. The second further chamber may be configured, for example, as an absorption chamber which is filled with sound-absorbing material. It is also conceivable to design the second further chamber also as an expansion chamber.

According to an advantageous development, the first further chamber may be designed as an absorption chamber which is filled with sound-absorbing material. The first further chamber may be separated from the expansion chamber by means of a first partition wall and from the second further chamber by means of a second partition wall. The partitions are arranged axially between the end floors and spaced apart from them and to each other axially. The acoustic connection of the first further chamber acting as absorption chamber can be via a perforation in the inlet pipe or via a perforation in the secondary outlet pipe or realized via a perforation in the first partition wall or via a perforation in the second partition wall. It is also conceivable to achieve the acoustic coupling by a combination of the above perforations. An embodiment is conceivable in which the first dividing wall and the second dividing wall are imperforated, while the auxiliary outlet pipe has a perforation in the first further chamber. It is also conceivable that the inlet pipe is passed through the first partition wall and is imperforate in the first further chamber.

In a preferred embodiment, the first partition may be perforated such that the first further chamber is acoustically coupled to the expansion chamber. If the second partition wall is imperforate, the acoustic coupling of the first further chamber takes place through the first partition with the expansion chamber. Alternatively, the second partition may also be provided with a perforation, so that the first further chamber is acoustically coupled to the expansion chamber and to the second further chamber.

In an alternative embodiment, on the other hand, it is provided that the first partition wall is imperforated, while the second partition is perforated, so that the acoustic connection of the first further chamber through the second partition to the second further chamber. Further, then inlet tube and Nebenauslassrohr are imperforate in the first further chamber, while the Nebenauslassrohr in the second further chamber has a perforation. Suitably, in this case, the second additional chamber is designed as an expansion chamber, so that airborne sound can reach the perforated second partition wall through a free space in the expansion chamber.

A preferred embodiment results when connected to the expansion chamber, an absorption chamber and when the absorption chamber a Resonance chamber connects. The absorption chamber may be acoustically connected to the expansion chamber through a perforation of the first partition wall. Likewise, the inlet tube may have a perforation in the overlap area located in the absorption chamber. The resonance chamber may be acoustically connected to the expansion chamber via a connecting tube, with the connecting tube penetrating both partitions. The second partition is expediently imperforated. The secondary outlet tube and the main outlet tube are expediently imperforate in this embodiment.

However, an embodiment in which two further chambers are formed in the housing, namely a first further chamber, which connects axially to the expansion chamber via a first partition wall, and a second, further chamber, which has a side remote from the expansion chamber, are particularly advantageous second partition axially adjoins the first further chamber, wherein the first further chamber is configured as an absorption chamber, which is filled with a sound-absorbing material and which is acoustically coupled by the perforated configured first partition with the expansion chamber, and wherein the second further chamber designed as a resonator is, which is separated by means of the unperforated second partition from the first further chamber and which is acoustically connected via a resonator to the Nebenauslassrohr or to the expansion chamber. Thus, a broadband attenuation can be realized by means of expansion, absorption and resonance via the secondary path.

Expediently, the main outlet line and the secondary outlet line extend parallel to one another within the housing. The arrangement of the tubes within the housing is expedient so that the exhaust gas must be deflected during operation of the internal combustion engine in the expansion chamber of an outlet opening of the gap over 180 ° to pass through the inlet opening of the Nebenauslassrohrs to be able to enter the Nebenauslassrohr. If the two outlet tubes are led out of the housing through the same end base, the arrangement of the inlet opening of the secondary outlet tube and the outlet opening of the gap is expediently such that the flow in the expansion chamber must be deflected twice by 180 ° in order to move from the outlet opening of the gap into the outlet chamber Entry opening of the Nebenauslassrohrs to get.

Suitably, the main outlet tube in the overlap region is radially supported on the inlet tube to reduce relative movement between the inlet tube and the main outlet tube. For this purpose, the main outlet pipe may be supported by a plurality of webs on the inlet pipe, which are distributed in the circumferential direction of the main outlet pipe and bridge the gap. Additionally or alternatively, it can be provided that the main outlet pipe is supported via at least one perforated ring on the inlet pipe, which extends in the circumferential direction of the main outlet pipe and fills the gap. In both cases, a significant stabilization is achieved, which is relatively inexpensive to implement.

In addition, it can be provided that the main outlet pipe is supported on a perforated intermediate bottom, which is arranged in the expansion chamber and supported on the housing. This measure also stabilizes the position of the main outlet pipe in the housing. The perforated intermediate floor leads to no acoustic separation within the expansion chamber, so that it remains as a unit.

According to an advantageous development, the main outlet pipe can be controlled by means of a control device with respect to its flow with exhaust gas. This control direction can be coupled inside the housing to the main outlet pipe or outside of it. This control device can in particular be configured so that it opens the main outlet pipe at least at full load of the internal combustion engine and that it locks the Hauptauslassrohr at least at low partial load of the internal combustion engine. Likewise, control devices are conceivable in which one, several or any number of intermediate positions can be realized. The control device can be configured so that it works actively, that is equipped with an actuator, or that it works passively and is therefore adjusted only by displacement forces of the flow. Likewise, a semi-active embodiment of the control device is conceivable, which operates for example with a pressure cell and is controlled by the pressure prevailing in the inlet tube and / or in the expansion chamber and / or in the initial region of the main outlet tube.

Other important features and advantages of the invention will become apparent from the dependent claims, from the drawing and from the associated description of the figures with reference to the drawing.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination given, but also in other combinations or in isolation, without departing from the scope of the present invention.

Preferred embodiments of the invention are illustrated in the drawings and will be explained in more detail in the following description.

The only FIG. 1 shows a much simplified schematic diagram of a muffler.

Corresponding Fig. 1 comprises a muffler 1, which is provided for an exhaust system of an internal combustion engine, a housing 2, which is preferably cylindrical is configured and accordingly has a cylindrical shell 3 and at its axial ends in each case an end bottom, namely a first end bottom 4 and a second end bottom 5. Suitably, the exhaust system and the internal combustion engine is arranged in a road vehicle. This is preferably a passenger car, in particular a sports car.

In the housing 2, an expansion chamber 6 is formed. It is characterized by a free space, can expand into the exhaust gas or airborne sound entrained therein. Outside this clearance, e.g. along boundary walls, may be arranged in the expansion chamber 6 optional sound absorption.

The muffler 1 is provided with an inlet pipe 7 having an end portion 8 in the housing 2, with which the inlet pipe 7 terminates in the expansion chamber 6. For this purpose, the end portion 8 in the expansion chamber 6 to an outlet opening 9. Further, the muffler 1 is equipped with a Hauptauslassrohr 10 having an initial portion 11 in the housing 2. This start portion 11 is inserted into the end portion 8 of the inlet pipe 7 and terminates inside the inlet pipe 7. Accordingly, the start portion 11 is in Fig. 1 shown only with a broken line. The initial section 11 has an inlet opening 12 within the inlet tube 7. Since the initial portion 11 of the main outlet pipe 10 protrudes into the end portion 8 of the inlet pipe 7, an overlapping area 13 is formed between the end portion 8 and the starting portion 11, which in FIG Fig. 1 indicated by a curly bracket. In this overlapping region 13, a gap 14 is formed radially between the end section 8 and the initial section 11. This gap 14 in turn forms a bypass which bypasses the initial section 11 within the end section 8. Thus, through the gap 14, exhaust gas from the inlet pipe 7 may pass outwardly past the initial section 11 into the expansion chamber 6 stream. Finally, the silencer 1 also has a secondary connection pipe 15, which has an inlet opening 16 in the expansion chamber 6.

Conveniently, the end portion 8 of the inlet tube 7 and the initial portion 11 of the main outlet tube 10 extend in a straight line, so that also the overlap region 13 is rectilinear. In this case, the initial portion 11 extends axially into the end portion 8 so far that the overlap region 13 has an axial length 17, which in the example shown is about four times as large as a diameter 18 of the inlet tube 7 in the end portion 8 the length 17 of the overlap region 13, a resonance effect in the main outlet pipe 10 can be optimized, with the targeted a certain frequency of the transported sound in the exhaust sound can be attenuated.

The flow-through cross-sections or flow resistance of the main outlet 10, the secondary outlet 15 and the gap 14 are suitably coordinated so that, at least at partial load and / or full load of the internal combustion engine, a predetermined distribution of a supplied via the inlet pipe 7 exhaust stream 19 to one through the Hauptauslassrohr 10 discharged main part stream 20 and adjusted by the Nebenauslassrohr 15 secondary partial flow 21 sets. The supplied total flow 19, the main partial flow 20 and the secondary partial flow 21 are in Fig. 1 indicated by arrows. Preferably, a division of the total flow 19 is set to the main partial flow 20 and the secondary partial flow 21, which is in a range of 40:60 to 60:40. Particularly advantageous is a division of about 50:50.

In order to achieve this division of the total flow 19 to the main partial flow 20 and the secondary partial flow 21, it can be provided in the overlap region 13 a cross-section of the gap 14 which is permeable on average approximately the same Accordingly, the flow-through cross sections of the gap 14 and the beginning portion 11 are each about half as large as the flow-through cross section of the inlet tube 7 immediately upstream of the inlet opening 12 of the Hauptauslassrohrs 10th

Although in Fig.1 a concentric arrangement of the starting portion 11 and the end portion 8 is shown, resulting in a completely annular around the initial portion 11 circumferential gap 14, basically any eccentric arrangement can be selected. In particular, it is also conceivable that the starting section 11 touches the end section 8 in a linear manner. It is likewise conceivable that the end section 8 and the start section 11 have a common wall section which is delimited in the circumferential direction of the overlapping section 13. The gap 14 may also have different geometries depending on the cross-sectional geometry of the starting section 11 and the end section 8 in the overlapping region 13. It may be, for example, annular or C-shaped with round tube cross-sections and U-shaped or I-shaped with angular, preferably rectangular, tube cross sections.

In the preferred embodiment shown here with a cylindrical housing 2, the inlet pipe 7 is passed through the jacket 3, while the outlet pipes 10 and 15 are passed through the end floors 4, 5. In detail, the main outlet pipe 10 is passed through the first end floor 4, while the sub-outlet pipe 15 is passed through the second end floor 5. Alternatively, it can also be provided that both outlet pipes 10, 15 are guided through the same end floor 4 or 5.

Furthermore, in the embodiment shown here in the housing 2, two further chambers, namely a first further chamber 22 and a second further Chamber 23 formed. The first further chamber 22 connects axially to the expansion chamber 6. The second additional chamber 23 adjoins the first further chamber 22 axially on a side facing away from the expansion chamber 6. The axial direction is defined by a longitudinal central axis 24 of the cylindrical housing 2. The first further chamber 22 is separated from the expansion chamber 6 by means of a first partition wall 25 and separated from the second further chamber 23 by means of a second partition wall 26. Preferred is an embodiment in which the first further chamber 22 is designed as an absorption chamber and is filled with a sound-absorbing material 27. Suitably, the first further chamber 22 is completely filled with sound-absorbing material 27. Furthermore, the first partition 25 is preferably perforated. The first further chamber 22 is thus acoustically connected to the expansion chamber 6. The first partition wall 25 is penetrated by the inlet pipe 7 and the secondary outlet pipe 15. The second partition wall 26 is preferably configured unperforated. The second additional chamber 23 can preferably be designed as an expansion chamber or as an absorption chamber or as a resonance chamber. Furthermore, an embodiment is preferred in which the inlet pipe 7 and the main outlet pipe 10 are unperforated. In contrast, the secondary outlet pipe 15 may be provided in the second further chamber 23 with a perforation 28, whereby the second further chamber 23 is acoustically coupled to the Nebenauslassrohr 15. The Nebenauslassrohr 15 may be unperforated in the first further chamber 22 or have another, not shown here perforation. In conjunction with the perforation 28, the second further chamber 23 forms a further expansion chamber.

Instead of the perforation 28 shown, a resonator pipe 29 indicated by a broken line can also be provided on the secondary outlet pipe 15, which in conjunction with the free volume of the second further chamber 23 Helmholtz resonator forms. The second further chamber 23 is then a resonance or resonator chamber.

Preferably, it may also be provided to use a resonator tube 32 for acoustically connecting the expansion chamber 6 with the second further chamber 23 in order to form such a Helmholtz resonator. Also in this case, the second additional chamber 23 is a resonator chamber. The resonator tube 32 penetrates the perforated first partition wall 25 and the unperforated second partition wall 26 and the first further chamber 22, which serves as an absorption chamber in this case. Further, in this case, the sub-outlet pipe 15 and the inlet pipe 7 are at least in the second further chamber 23, respectively, unperforated.

Likewise, it is alternatively conceivable, in addition to the perforation 28, to provide a connecting tube 30 which is in Fig. 1 also indicated only with a broken line. This connecting tube 30 then interacts with the free volume of the first further chamber 22 as a Helmholtz resonator. In this case, it may be expedient to design the second further chamber 23, which is acoustically connected via the perforation 28 to the secondary outlet line 15, as an absorption chamber, which is then filled with sound-absorbing substance 27.

In Fig. 1 In addition, a control device 31 is indicated, with the aid of which the flowability of the main outlet pipe 10 can be controlled with exhaust gas. In particular, the distribution of the total flow 19 to the main partial flow 20 and the secondary partial flow 21 can thereby be varied. For example, at full load of the internal combustion engine, the control device 31 can open the main outlet pipe 10, so that a comparatively large main partial flow 20 is created. In contrast, in a lower part-load range, the control device 31 may cause a blockage of the main outlet pipe 10, so that then a comparatively large Secondary partial flow 21 is formed, which corresponds to the total flow 19 in the extreme case. In the example shown, this optional control device 31 is arranged outside of the housing 2. In another embodiment, the control device 31 may also be arranged on the housing 2 or in the housing 2.

According to Fig. 1 is also provided that the main outlet pipe 10 is supported radially in the overlap region 13 on the inlet pipe 7. This is achieved in the example shown in the region of the inlet opening 12 of the Hauptauslassrohrs 10 by means of a plurality of webs 33 which support the Hauptauslassrohr 10 on the inlet tube 7, which are distributed in the circumferential direction of the Hauptauslassrohrs 10 and spaced from each other and which bridge the gap 14. In addition, in the example in the region of the outlet opening 9 of the inlet pipe 7, a perforated ring 34 is provided, via which the main outlet pipe 10 is supported on the inlet pipe 7, which extends in the circumferential direction of the main outlet pipe 10 and fills the gap 14. Finally, it is additionally or alternatively provided here that the main outlet pipe 10 is supported on a perforated intermediate bottom 35, which is arranged in the expansion chamber 6 and supported on the housing 2.

In the overlap region 13, a tube-in-tube arrangement of the inlet tube 7 and the main outlet tube 10 is thus created, which virtually allows an uninterrupted flow through the housing 2 when the main outlet tube 10 is open. By means of this tube-in-tube arrangement, an exhaust main path through the housing 3 is thus created. In addition, if the inlet pipe 7 and the main outlet pipe 10 are unperforated and in particular in the overlap region 13 of the end portion 8 and the initial portion 11 are imperforate done via this quasi-continuous tube only a very small acoustic coupling with the acoustic damping means of the muffler 1. In particular, only comparatively little volume of the muffler 1 to this Main path coupled. These acoustic damping means are, for example, as explained above, the expansion chamber 6, the first additional chamber 22 and the second additional chamber 23, which can serve either as an expansion chamber, as an absorption chamber or as a resonance chamber of a Helmholtz resonator. When the main outlet pipe 10 is open, the airborne sound entrained in the overall flow 19 can escape from the muffler 1 through the main outlet pipe 10 substantially unattenuated along the exhaust main path, giving the driver the desired acoustic feedback. If, on the other hand, the main outlet pipe 10 is blocked, the airborne sound entrained in the overall flow 19 is forced to follow the exhaust gas bypass path guided through the auxiliary outlet pipe 15, with all the intended damping means being active and correspondingly effective damping of the entrained airborne sound. Furthermore, the coupling of the main outlet tube 10 acting as a resonance tube can be optimized by the tube-in-tube arrangement.

Claims (15)

Silencer for an exhaust system of an internal combustion engine, preferably a road vehicle, - With a housing (2) in which an expansion chamber (6) is formed, inlet tube (7) which leads into the housing (2) with an exhaust gas and has an end section (8) in the housing (2) which has an outlet opening (9) in the expansion chamber (6), with a main outlet pipe (10) leading out of the housing (2) and having in the housing (2) an initial section (11) which projects into the end section (8) of the inlet pipe (7), with a gap (14) formed in an overlapping area (13) between the end portion (8) of the inlet pipe (7) and the start portion (11) of the main outlet pipe (10), which in the end portion (8) of the inlet pipe (7) has a gap Beginning portion (11) of the Hauptauslassrohrs (10) bypass forms by which exhaust gas from the inlet pipe (7) in the expansion chamber (6) can flow, - With a waste gas from the housing (2) out leading Nebenauslassrohr (15), which has an inlet opening (16) in the expansion chamber (6). Silencer according to claim 1,
characterized, - That the end portion (8) of the inlet tube (7) and the initial portion (11) of the Hauptauslassrohrs (10) are rectilinear, - That an axial length (17) of the overlap region (13) is at least twice as large as a diameter (18) of the end portion (8) of the inlet tube (7). Silencer according to claim 1 or 2,
characterized,
that the through-flow cross-sections and / or the flow resistances of the main exhaust pipe (10), Nebenauslassrohr (15) and gap (14) are matched to one another that supplied at partial load of the internal combustion engine via the intake pipe (7) the exhaust gas stream (19) in a proportion of 40% to 60% is discharged through the main outlet pipe (10). Silencer according to one of claims 1 to 3,
characterized,
that in the overlap region (13), a flow-through cross-section of the gap (14) is approximately the same on average as a cross-section through which the main outlet tube (10) can flow. Silencer according to one of claims 1 to 4,
characterized, - That the housing (2) is cylindrical and has a jacket (3) and two end floors (4, 5), - That the inlet tube (7) passes through the jacket (3), that the main outlet pipe (10) passes through the one end floor (4), - That the Nebenauslassrohr (15) passes through the other end floor (5). Silencer according to one of claims 1 to 5,
characterized, - That the inlet tube (7) is imperforate, and / or - That the Hauptauslassrohr (10) is imperforate, and / or - That the Nebenauslassrohr (15) is imperforate. Silencer according to one of claims 1 to 5,
characterized,
that the inlet pipe (7) in the overlap region (13) has a perforation. Silencer according to one of claims 1 to 7,
characterized, - That in the housing (2) at least one further chamber (22, 23) is formed, - That the inlet tube (7) and / or the Nebenauslassrohr (15) at least in such a further chamber (22, 23) has a perforation (28) / have. Silencer according to one of claims 1 to 8,
characterized, - that in the housing (2) has two further chambers (22, 23) are formed, namely a first further chamber (22) via a first partition wall (25) axially to the expansion chamber (6), and a second further chamber ( 23) which adjoins the first further chamber (22) axially at a side remote from the expansion chamber (6) via a second partition wall (26), - That the first further chamber (22) is designed as an absorption chamber, which is filled with a sound-absorbing material (27) and which is acoustically coupled via the perforated first partition wall (25) with the expansion chamber (6), - That the second further chamber (23) is designed as a resonator, which is separated via the imperforate second partition wall (26) of the first further chamber (22) and acoustically on a resonator tube (29; the Nebenauslassrohr (15) or to the expansion chamber (6) is connected. Silencer according to one of claims 1 to 9,
characterized,
in that the main outlet pipe (10) is supported radially on the inlet pipe (7) in the overlapping area (13). Silencer according to claim 10,
characterized,
in that the main outlet pipe (10) is supported on the inlet pipe (7) by a plurality of webs (33) distributed in the circumferential direction of the main outlet pipe (10) and bridging the gap (14). Silencer according to claim 10 or 11,
characterized,
that the main exhaust pipe (10) via at least one perforated ring (34) at the inlet pipe (7) is supported, which extends in the circumferential direction of the Hauptauslassrohrs (10) and fills the gap (14). Silencer according to one of claims 1 to 12,
characterized,
in that the main outlet pipe (10) is supported on a perforated intermediate floor (35) which is arranged in the expansion chamber (6) and supported on the housing (2). Silencer according to one of claims 1 to 13,
characterized,
in that the main outlet pipe (10) is controlled by means of a control device (31) with respect to the flow of exhaust gas which opens the main outlet pipe (10) at least at full load of the internal combustion engine and blocks the main outlet pipe (10) at least at low partial load. Exhaust system for an internal combustion engine, in particular of a motor vehicle, having an exhaust gas line, which leads from at least one exhaust manifold to at least one tail pipe and in which at least one silencer (1) according to one of claims 1 to 14 is arranged.

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