DE102015223680A1 - silencer - Google Patents

Abstract

The present invention relates to a silencer (1) for an exhaust system of an internal combustion engine, comprising a housing (2) having a circumferentially extending sheath (5) with a Helmholtz resonator (11) having a resonator (12) and a Resonator tube (13), wherein the resonator chamber (12) radially from the shell (5) and axially delimited by an intermediate bottom (7), wherein the resonator tube (13) penetrates the intermediate bottom (7) and there by means of a molding and / or frictional connection (15) is axially fixed. To extend the resonator tube (13), it is proposed to provide the resonator tube (13) in the resonator chamber (12) with an overtube (24) which encloses an end section (25) of the resonator tube (13) and which is connected to one of the intermediate bottom (7). the end (26) is closed off, wherein the resonator tube (13) is fluidically connected to the resonator chamber (12) through a gap (27) formed radially between the overtube (24) and the resonator tube (13).

Description

The present invention relates to a muffler for an exhaust system of an internal combustion engine.

Silencers with housing usually have a circumferentially encircling shell and two axial ends. In the housing, at least one intermediate bottom can be arranged axially between the ends. Such shelves serve on the one hand to auszusteifen the case. On the other hand, such shelves can also be used to position or hold tubes within the housing. In principle, a welded connection can be used to fasten such a pipe to an intermediate floor. However, it has been found that welds in the, usually ferritic, alloys used to make the tubes and shelves in silencers increase the risk of intergranular corrosion. It is therefore increasingly transferred to fasten such pipes by means of positive and / or non-positive connections on the respective intermediate floor. Such form and / or frictional connections come without material connection, whereby the risk of intergranular corrosion is significantly reduced. Such positive and / or frictional connections are, for example, compounds which are associated with a plastic deformation on the tube and / or on the intermediate bottom in order to bring about the desired fixation. Particularly advantageous in this case, a rib fixation has been found. For this purpose, the intermediate bottom in the region of an opening, in which the respective tube is to be inserted, equipped with a ring collar. Then the pipe is inserted into the opening, so that the ring collar runs around the outside of the pipe. Subsequently, two ribs are formed on the tube by plastic deformation, which protrude axially on both sides of the annular collar radially outwardly from the remaining outer contour of the tube. As a result, the annular collar and thus the intermediate floor is axially fixed between these two ribs by positive locking. The respective rib can be configured as an annular rib which extends annularly in the circumferential direction or can be formed by a plurality of rib segments distributed in the circumferential direction. For such a rib fixation only tubes with a comparatively large diameter currently come into consideration.

In mufflers Helmholtz resonators are often used, which have a resonator and a resonator tube, which is often referred to as a neck. Such a Helmholtz resonator is not flowed through by the exhaust gas, but only fluidly or acoustically coupled to the exhaust gas flow. The resonant frequency of such a Helmholtz resonator is determined by the volume enclosed by the resonator chamber and by the dimensions of the resonator tube. The dimensions of the resonator tube are determined at least by the diameter of the resonator tube and by the length of the resonator tube. In this case, for the resonant frequency of the Helmholtz resonator with respect to the dimensions of the Resonatorrohrs on the one hand, a proportional relationship with the pipe diameter, while on the other hand with the pipe length is a reciprocal proportional relationship. This means that the resonance frequency can be increased on the one hand by increasing the pipe diameter and on the other hand by reducing the pipe length.

In order to fix such a resonator tube by means of a rib fixation on at least one intermediate floor, the resonator tube must be provided with a relatively large diameter. Due to the relationship described above between the resonant frequency and the dimensions of the resonator tube, an increase in the tube diameter also requires an increase in the tube length if the resonant frequency is to remain constant. By specifying a comparatively large diameter for the resonator tube, problems may therefore arise in silencers which have a relatively small, predetermined installation space. In particular, the required length for the resonator tube may be greater than the installation space available in the muffler for this purpose.

The present invention is concerned with the problem of providing an improved embodiment for a silencer of the type described above, which is particularly characterized in that on the one hand a Helmholtz resonator can be realized, while on the other hand, the resonator tube by means of a positive and / or non-positive connection at one the resonator space limiting intermediate floor can be attached.

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 extending the resonator tube within the resonator cavity by means of a tube-in-tube arrangement. For this purpose, an end section of the resonator tube is inserted into an overtube inside the resonator chamber. The overtube is closed at the end, which faces away from the intermediate bottom, which is penetrated by the resonator tube. The overtube has an inner cross section which is larger than an outer cross section, the Resonator tube has in its end portion. As a result, an additional space is formed radially between the overtube and the resonator, through which the fluidic and acoustic coupling between the resonator tube and resonator takes place. In that regard, the length of the overtube can be added to the length of the resonator tube. Likewise, the volume of the additional space can be added to the volume enclosed by the resonator tube. As a result, a sufficient length for the resonator tube can be realized even with a relatively large cross-section of the resonator tube in order to realize a Helmholtz resonator with the respective desired resonant frequency in the muffler. As a result, the form and / or frictional connection for axially fixing the resonator tube to the intermediate floor can be realized.

Advantageously, an embodiment in which the overtube is axially secured by means of a spaced axially from the intermediate bottom separate form and / or frictional connection on the resonator tube. In particular, it can be provided that the overtube is fastened exclusively to the resonator tube, so that it is radially and axially spaced in the resonator chamber from the rest of the housing.

Alternatively, it is also possible to fix the overtube to the housing so that it has no connection to the resonator tube. In particular, then the resonator tube ends free-standing within the overtube. In this case, the overtube in the resonator can also end free-standing.

In another alternative it can be provided that the overtube to the resonator tube is arranged contactless and radially spaced at the intermediate bottom is supported. This can lead to a simplified production.

The respective positive and / or non-positive connection can be produced by means of a plastic deformation of the resonator tube and / or the intermediate bottom in the region of the connection.

In another, particularly advantageous embodiment, the overtube can protrude into the intermediate bottom and be attached axially thereto by means of the positive and / or non-positive connection on the resonator tube. As a result, more axial length is available for the overtube. In addition, the production is simplified.

Suitably, the respective positive and / or non-positive connection may have an annular collar formed on the intermediate bottom or on the overtube which encloses the resonator tube in the circumferential direction. Likewise, the respective positive and / or non-positive connection may have two ribs formed on the resonator tube, which are arranged axially on both sides of the respective annular collar for the axial attachment of the annular collar on the resonator tube. Suitably, an outer cross section of the ribs is greater than an inner cross section of the respective annular collar. Thus, the respective annular collar is axially fixed by the two ribs by positive engagement on the resonator tube. Such a form and / or frictional connection may also be referred to as rib fixation. The ribs can be produced by plastic deformation of the resonator tube, e.g. by means of a hydraulic hydroforming process. Optionally, the region of the resonator tube lying axially between the ribs can also be radially plastically expanded, ie calibrated, in order to press it with the annular collar. Machines for producing such rib fixations are e.g. offered by Upland Technologies Inc. of Cambridge, Ontario, Canada under the name "Ridge Lock Machine".

Within such a rib fixation, the respective annular collar can abut axially between the ribs radially on the outside of the resonator tube. If a common rib fixation is provided for the intermediate bottom and the overtube on the resonator tube, expediently only one annular collar is supported radially on the outside of the resonator tube, while the other annular collar is then supported radially on the outside of this annular collar.

Preferred is an embodiment in which the annular collar of the overtube is arranged radially between the resonator tube and the annular collar of the intermediate bottom.

If the overtube is arranged without contact with the resonator, it may be provided in another embodiment, that the annular collar of the intermediate bottom forms an inner U-leg of the resonator tube in the circumferential direction enclosing U-shaped edge portion of the intermediate bottom, wherein the overtube radially on an outer U -Skel of this edge region is supported on a side facing away from the resonator tube side. A U-base, which connects the two U-legs together, is then facing the additional space and limits this axially. This results in a particularly easy to implement embodiment.

In another advantageous embodiment, the over-tube can be axially closed at its end remote from the intermediate tube penetrated by the resonator tube end by the housing or its shell or by another intermediate bottom, which limits the resonator axially. Here, a communicating connection between the resonator tube and Extra space particularly easy to realize that the resonator tube is arranged with an open end axially spaced from this closed end of the overtube.

Alternatively, the over-tube may be axially closed off at its end facing away from the latter, which is penetrated by the resonator tube, by means of a separate cover which is fastened to the overtube. In this case, the resonator tube carries the overtube, while the overtube is spaced with the lid to the housing, so has no contact. As a result, thermally induced stresses can be avoided, which can occur when the overtube is supported on the one hand on the housing and on the other hand on the resonator tube.

In an advantageous embodiment, the intermediate space can be fluidically connected to the resonator tube via a proximal connection, which is located in the region of one end of the resonator tube, and via a distal, axially spaced distal connection located at the over tube in an area remote from the end of the resonator tube , be fluidly connected to the resonator. The axial distance between the proximal connection and the distal connection corresponds to the extension of the resonator tube, which is achieved by means of the overtube. Suitably, the additional space has no further fluidic connection to the resonator tube and to the resonator chamber, so that only the proximal connection and the distal connection are provided. The acoustic coupling between the resonator tube and the resonator cavity thus takes place through the proximal connection, through the intermediate space and through the distal connection.

According to an advantageous development, the proximal connection can be formed by a gap between the closed end of the overtube and the open end of the resonator tube. Alternatively, the proximal connection can be formed by a perforation formed on the tube, wherein the end of the resonator tube is closed. In particular, a common cover may be provided for closing the end of the resonator tube and the end of the overtube, which is fastened to the resonator tube and / or to the overtube. Such a lid may for example be pressed or jammed or crimped with the respective tube.

In another development, the distal connection may be formed by a perforation formed on the over tube.

The respective perforation may have a plurality of openings distributed in the circumferential direction.

For the housing of the muffler come basically any designs into consideration, e.g. Half-shell construction, wound construction, tube or barrel construction. In a preferred embodiment it can therefore be provided that the shell of the housing is formed by a jacket extending in the circumferential direction, wherein the axial ends of the housing are each formed by a separate end bottom with respect to the shell. The intermediate floor is then arranged axially between these end floors and spaced therefrom. Alternatively, an embodiment is also conceivable in which the sheath is formed by two half-shells, which also form the axial ends of the housing.

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

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 described in more detail in the following description, wherein like reference numerals refer to the same or similar or functionally identical components.

Show, in each case schematically,

1 a simplified schematic diagram of a silencer in longitudinal section,

2 a greatly simplified sectional view in the region of a Helmholtz resonator,

3 to 5 each an enlarged sectional view of the Helmholtz resonator in the region of an overtube in various embodiments,

6 a sectional view as in 2 but in another embodiment.

Corresponding 1 includes a silencer 1 , which is suitable for use in an exhaust system of an internal combustion engine, preferably a road vehicle, a housing 2 , whose longitudinal central axis 3 an axial direction 4 defined, which is indicated in the figures by a double arrow. The housing 2 may have any square and non-angular cross-section, such as a rectangular, square, circular or elliptical or oval cross-section. The casing 2 has a peripheral circumferential shell 5 and two axial ends 6 , The housing 2 can be manufactured eg in winding construction or in barrel or pipe construction. Then according to the in 1 example shown the shell 5 by a closed in the circumferential direction circumferential jacket 43 educated. At the axial ends 6 then there are end floors 44 that the case 2 at the two axial ends 6 close. It is clear that the case 2 basically also be made in half-shell construction. Then at least the two end floors are missing 44 ,

The silencer 1 can be inside the case 2 at least one intermediate floor 7 . 8th . 9 . 10 having axially between the two ends 6 or between the end floors 44 arranged and from the shell 5 or from the coat 43 is enclosed. In the example shown the 1 are four shelves 7 . 8th . 9 . 10 provided, of which in principle only the reference numeral 7 provided intermediate floor 7 is required while on the other shelves 8th . 9 . 10 basically can be waived. Subsequently, these intermediate floors for better distinction as the first, second, third and fourth intermediate floor 7 . 8th . 9 . 10 according to their sequence in 1 be designated from right to left.

The silencer 1 contains a Helmholtz resonator 11 , in the operation of the muffler 1 does not flow through the exhaust gas. The Helmholtz resonator 11 has a resonator space 12 and a resonator tube 13 , About the resonator tube 13 is one in the operation of the muffler 1 Exhaust gas flow area 14 acoustically and fluidically with the resonator chamber 12 coupled. The resonator room 12 is radial from the shell 5 or from the coat 43 and axially on the one hand from said first intermediate floor 7 limited. Axial, on the other hand, is the resonator cavity 12 eg through the housing 2 , in the example shown by one of the end floors 44 limited. The resonator tube 13 penetrates the first intermediate floor 7 and is there by means of a positive and / or frictional connection 15 axially fixed, which below with respect to the 2 to 6 will be explained in more detail.

In the example of 1 closes axially to the resonator chamber 12 an expansion chamber 16 or an absorption chamber 16 at. The absorption chamber 16 is different from the expansion chamber 16 in that the absorption chamber 16 filled with a sound-absorbing material. The expansion chamber 16 or absorption chamber 16 is axially through the first and second intermediate floor 7 . 8th and radially through the shell 5 or the coat 43 limited and completely from the resonator tube 13 interspersed. Accordingly, the resonator tube penetrates 13 also the second intermediate floor 8th , the second intermediate floor 8th on the resonator tube 13 also by a positive and / or non-positive connection 15 can be attached.

In the case 2 is also an inlet chamber 17 formed into which an inlet pipe 42 opens, this the coat 43 interspersed. A connecting pipe 18 connects the inlet chamber 17 with a deflection chamber 19 , The deflection chamber 19 is radial through the jacket 43 and axially through the other end floor 44 as well as through the fourth intermediate floor 10 limited. The fourth intermediate floor 10 is here with a perforation 20 equipped, whereby the deflection chamber 19 with an exit chamber 21 is fluidically connected, from an outlet pipe 22 out leads. The outlet pipe 22 passes through the fourth intermediate floor 10 and the other end floor 44 , Here, the outlet pipe 22 at the end floor 44 and at the intermediate floor 10 each with a positive and / or non-positive connection 15 be fixed.

The exit chamber 21 is radial from the jacket 43 and axially from the third intermediate floor 9 and from the fourth intermediate floor 10 limited. The connecting pipe 18 passes through the third intermediate floor 9 and the fourth intermediate floor 10 and can each by means of a positive and / or frictional connection 15 be attached. For the connection of the inlet pipe 42 with the coat 43 and for the connection of the outlet pipe 22 with the respective end floor 44 a welded joint may be preferred to achieve the required tightness.

During operation of the exhaust system results in a 1 indicated by arrows exhaust stream 23 through the muffler 1 , The flowed through area 14 thus includes the inlet tube 42 , the entry chamber 17 , the connecting pipe 18 , the deflection chamber 19 , the exit chamber 21 and the outlet pipe 22 , The resonator tube 13 is to the entrance chamber 17 fluidly connected so that the resonator cavity 12 over the resonator tube 13 acoustically to the exhaust gas leading area 14 connected. The expansion chamber 16 or the absorption chamber 16 can acoustically pass through a perforation to the exhaust leading area 14 be connected, either directly through a second intermediate floor 8th formed perforation or indirectly by a in the first intermediate floor 7 trained perforation or by a resonator tube 13 inside the expansion chamber 16 or the absorption chamber 16 trained perforation. Preferably, it is provided here that the resonator tube 13 inside the expansion chamber 16 or absorption chamber 16 is imperforate and that the first intermediate floor 7 that the resonator room 12 axially limited, also unperforated.

According to the 1 to 6 is the resonator tube 13 in the resonator room 12 with an overtube 24 equipped, in which an end section 25 of the resonator tube 13 is inserted axially. As a result, the overtube envelops 24 the end section 25 , Furthermore, the overtube 24 at one of the first intermediate floor 7 opposite end 26 locked. An inner cross section of the overtube 24 and an outer cross section of the resonator tube 13 in the end section 25 are coordinated so that radially between the overtube 24 and the resonator tube 13 an additional room 27 is trained. This additional room 27 on the one hand with the resonator tube 13 and on the other hand, with the resonator space 12 fluidically and acoustically in connection. The result is the resonator tube 13 through this gap 27 through to the resonator chamber 12 fluidically and acoustically connected.

While at the in 1 indicated simplified embodiment of the overtube 24 in the resonator room 12 freestanding ends so that there is no connection to the resonator tube 13 show, the show 2 to 5 preferred embodiments in which the overtube 24 on the resonator tube 13 is attached. In the example of 6 is the overtube 24 on the other hand, on the intermediate floor 7 attached. Preference is given to the axial attachment of the resonator tube 13 on the overtube 24 also a form and / or traction connection 15 for use. In the examples of 2 and 3 is the form and / or frictional connection 15 for attaching the overtube 24 on the resonator tube 13 axially spaced and thus separate to the positive and / or frictional connection 15 formed, with the first intermediate floor 7 on the resonator tube 13 is attached. In 2 is also apparent that the resonator tube 13 via another form and / or frictional connection 15 with the second intermediate floor 8th axially fixed.

In the embodiments of the 4 and 5 extends the overtube 24 axially to the first intermediate floor 7 into it. As a result, the overtube can 24 together with this first intermediate floor 7 by means of a common form and / or frictional connection 15 on the resonator tube 13 be attached.

In the embodiments shown here, the respective form and / or frictional connection 15 designed as a rib fixation. This is on the respective intermediate floor 7 . 8th as well as on the overtube 24 one ring collar each 28 . 29 . 30 educated. The first intermediate floor 7 shows the ring collar 28 , At the overtube 24 is the ring collar 29 formed. At the second intermediate floor 8th is according to 2 the ring collar 30 educated. The respective ring collar 28 . 29 . 30 encloses the resonator tube 13 in its circumferential direction. Furthermore, the respective rib fixation, which also follows in the following 15 is denoted on the resonator tube 13 two radially outwardly projecting bead-like ribs 31 respectively. 32 respectively. 33 , Ribs 31 are axially on both sides of the ring collar 28 of the first intermediate floor 7 educated. Ribs 32 are axially on both sides of the ring collar 29 of the overtube 24 arranged. Ribs 33 are axially on both sides of the ring collar 30 of the second intermediate floor 8th arranged. In the example of 4 are the ring collar 28 of the first intermediate floor 7 and the ring collar 29 of the overtube 24 between the two ribs 31 arranged. Ribs 31 . 32 . 33 are on the ring collar 28 . 29 . 30 tuned so that an outer diameter of the respective annular rib 31 larger than an inner diameter of the respective associated, thus axially fixed annular collar 28 . 29 . 30 ,

In the preferred examples shown here, the ribs are 31 . 32 . 33 each as in the circumferential direction of the resonator tube 13 annular annular ribs designed. Alternatively, these ribs can be 31 . 32 . 33 also by a plurality in the circumferential direction of the resonator tube 13 realize distributed rib segments.

Ribs 31 . 32 . 33 For example, by means of a plastic forming process on the resonator tube 13 be formed while the ring collar 28 . 29 . 30 already on the resonator tube 13 are deferred. At the same time, a radial compression between the outside of the resonator tube 13 and an inside of the respective annular collar 28 . 29 . 30 respectively. The plastic deformation can be realized for example by means of a hydraulic hydroforming process. Likewise, mechanical forming processes come into consideration, such as the above-mentioned Ridge-Lock method of Upland Technologies Inc.

According to 4 can be provided that the ring collar 29 of the overtube 24 radially between the resonator tube 13 and the ring collar 28 of the false floor 7 is arranged. In principle, however, a reverse arrangement is conceivable. This would have the ring collar 28 of the false floor 4 be angled in the opposite direction.

In the examples of 1 and 2 is the overtube 24 at his from the first intermediate floor 7 opposite end 26 through the end floor 6 axially closed. In contrast, the show 3 to 5 Embodiments in which the overtube 24 at this from the first intermediate floor 7 opposite end 26 through a lid 34 is axially closed. In these embodiments, it is further provided that by means of the lid 34 at the same time also in the overtube 24 arranged end 35 of the resonator tube 13 is axially closed. In contrast, in the examples of the 1 and 2 the end said 35 of the resonator tube 13 axially open.

The additional room 27 is axially on the one hand via a proximal connection 36 with the resonator tube 13 fluidly connected while axially on the other hand via a distal connection 37 with the resonator space 12 is fluidically connected. The proximal connection 36 is in the area of the end 35 of the resonator tube 13 that is inside the overtube 24 is arranged. The distal connection 37 is on the other hand at the over tube 24 , and in one of said end 35 of the resonator tube 13 axially spaced area. Appropriately has the overtube 24 apart from the distal connection 37 no further fluidic connection to the resonator chamber 12 , Also the resonator tube 13 owns apart from the proximal connection 36 no further fluidic connection with the additional room 27 ,

In the examples of 1 . 2 and 6 is the proximal connection 36 through an axial gap 38 formed axially between the closed end 26 of the overtube 24 and the open end of the resonator tube 35 is formed.

In the examples of 3 to 5 is the proximal connection 36 through one on the resonator tube 13 trained perforation 39 educated. These examples are the end 35 of the resonator tube 13 axially closed.

In the example of 1 is the distal connection 37 through a radial gap 40 educated. In contrast, among the 2 to 6 the distal connection 37 each by one in the overtube 24 trained perforation 41 educated.

In the in the 1 and 6 embodiments shown is the overtube 24 to the resonator tube 13 arranged contactlessly. While in the example of the 1 at its the intermediate floor 7 facing end ends free-standing and thus axially to the intermediate floor 7 it is in the example of the 6 at the intermediate floor 7 supported, and radially spaced from the resonator tube 13 , Furthermore, in 6 provided that the intermediate floor 7 a U-shaped edge area 46 one of the resonator tube 13 interspersed passage opening 48 encloses in the circumferential direction. Consequently, the border area encloses 46 also the resonator tube 13 in the circumferential direction. The border area 46 has in profile a radially inner inner U-legs 45 , a radially outer outer U-leg 47 and a U base 49 which the two U-thighs 45 . 47 connects with each other. The U base 49 is the gap 27 facing. As a result, the inner U-leg forms 45 the above-mentioned ring collar 28 of the false floor 7 , The overtube 24 is axial to the edge area 46 attached and radially to the outer U-leg 47 supported. The edge area 46 axially opposite is at the end floor 44 a depression 50 formed, which is an annular step 51 forms. On this ring step 51 is the overtube 24 also axially mounted and radially supported thereon.

Claims (15)

Silencer for an exhaust system of an internal combustion engine, - with a housing ( 2 ), which has a circumferentially extending envelope ( 5 ), - with a Helmholtz resonator ( 11 ), which has a resonator space ( 12 ) and a resonator tube ( 13 ), wherein the resonator space ( 12 ) radially from the shell ( 5 ) and axially from an intermediate floor ( 7 ) axially between two axial ends ( 6 ) of the housing ( 2 ), - wherein the resonator tube ( 13 ) the intermediate floor ( 7 ) penetrates and thereto by means of a positive and / or frictional connection ( 15 ) is axially fixed, - wherein the resonator tube ( 13 ) in the resonator space ( 12 ) with an overtube ( 24 ), which has an end section ( 25 ) of the resonator tube ( 13 ) and at one of the intermediate floor ( 7 ) facing away from the end ( 26 ) is closed, - wherein the resonator tube ( 13 ) by a radially between the overtube ( 24 ) and the resonator tube ( 13 ) formed space ( 27 ) through the resonator space ( 12 ) is fluidly connected. Silencer according to claim 1, characterized in that the overtube ( 24 ) by means of a form and / or frictional connection ( 15 ) on the resonator tube ( 13 ) is axially fixed. Silencer according to claim 1 or 2, characterized in that the overtube ( 24 ) to the intermediate floor ( 7 protrudes and with this together by means of the positive and / or frictional connection ( 15 ) on the resonator tube ( 13 ) is axially fixed. Silencer according to claim 1, characterized in that the overtube ( 24 ) to the resonator tube ( 13 ) arranged contactless and radially spaced at the intermediate bottom ( 7 ) is supported. Silencer according to one of claims 1 to 4, characterized in that the respective form and / or frictional connection ( 15 ) one on the intermediate floor ( 7 ) and / or on the overtube ( 24 ) trained ring collar ( 28 . 29 ), the resonator tube ( 13 ) encloses in the circumferential direction, and two on the resonator tube ( 13 ) formed ribs ( 31 . 32 ), which for axially fixing the Ring collar ( 28 . 29 ) on the resonator tube ( 13 ) axially on both sides of the respective annular collar ( 28 . 29 ) are arranged and whose outer diameter is greater than an inner diameter of the respective annular collar ( 28 . 29 ). A silencer according to claims 3 and 5, characterized in that the annular collar ( 29 ) of the overtube ( 24 ) radially between the resonator tube ( 13 ) and the ring collar ( 28 ) of the intermediate floor ( 7 ) is arranged. Muffler according to claims 4 and 5, characterized in - that the annular collar ( 28 ) of the intermediate floor ( 7 ) an inner U-leg ( 45 ) one the resonator tube ( 13 ) in the circumferential direction enclosing U-shaped edge region ( 46 ) of the intermediate floor ( 7 ), - that the overtube ( 24 ) radially on an outer U-leg ( 47 ) of this border area ( 46 ) is supported. Silencer according to one of claims 1 to 7, characterized in that the overtube ( 24 ) at its from the intermediate floor ( 7 ) facing away from the end ( 26 ) through the housing ( 2 ) or is axially closed by a further intermediate bottom, the resonator space ( 12 ) axially limited. Silencer according to one of claims 1 to 8, characterized in that the overtube ( 24 ) at its from the intermediate floor ( 7 ) facing away from the end ( 26 ) through a lid ( 34 ) is axially closed, the at the overtube ( 24 ) is attached. Silencer according to one of claims 1 to 9, characterized in that the additional space ( 27 ) via a proximal connection ( 36 ), which are in the range of one end ( 35 ) of the resonator tube ( 13 ), with the resonator tube ( 13 ) is fluidically connected and via a distal axial connection thereof ( 37 ), which are located on the overtube ( 24 ) in one of the end ( 35 ) of the resonator tube ( 13 ) is located with the resonator space ( 12 ) is fluidly connected. Silencer according to claim 10, characterized in that the proximal connection ( 36 ) through a gap ( 38 ) between the closed end ( 26 ) of the overtube ( 24 ) and the open end ( 35 ) of the resonator tube ( 13 ) is formed. Silencer according to claim 10, characterized in that the proximal connection ( 36 ) by a resonator tube ( 13 ) formed perforation ( 39 ), the end ( 35 ) of the resonator tube ( 13 ) is closed. Silencer according to claim 12, characterized in that a common cover ( 34 ) for closing the end ( 35 ) of the resonator tube ( 13 ) and the end ( 26 ) of the overtube ( 24 ) is provided, which at the resonator tube ( 13 ) and / or on the overtube ( 24 ) is attached. Silencer according to one of claims 10 to 13, characterized in that the distal connection ( 37 ) through an overtube ( 24 ) formed perforation ( 41 ) is formed. Silencer according to one of claims 1 to 14, characterized in that - the shell ( 5 ) of the housing ( 2 ) by a circumferentially extending jacket ( 43 ) is formed, wherein the axial ends ( 6 ) of the housing ( 2 ) each with respect to the shell ( 43 ) separate end floor ( 44 ), or - that the envelope ( 5 ) is formed by two half-shells, which are also the axial ends ( 6 ) of the housing ( 2 ) form.

Images