EP1510666A2 - Resonator - Google Patents

Abstract

The resonator collar (9) connects the pipe (5) with a resonator volume (6). This has a constant internal cross sectional area, avoiding flow constriction, and a variable inner cross sectional geometry along its length (11).

Description

The present invention relates to a resonator for treatment of airborne sound, resulting in a gas pipe spreads.

Gas-carrying lines in which airborne sound propagates, come in many areas of technology, for example in an exhaust system or in an intake system of an internal combustion engine, especially in a motor vehicle. Other Applications include, for example, cables connected to a fan or connected to a pump.

To avoid unwanted noise emission in the environment of the respective Reduce the line and / or the sound spectrum of the sound emitted into the environment in a desired To influence the way resonators are used, the have a resonator volume, which via a resonator neck communicating with the line. This can the airborne sound propagating in the line over the resonator neck also enter the resonator volume. The resonator volume and the resonator neck can be so interpret that for a predetermined frequency or for a predetermined frequency band resonance effects arise, which affect the airborne sound in the pipe. Usually is a damping of the respective frequency or the respective Frequency band achieved. The resonator is usually a so-called "Helmholtz resonator". One such Helmholtz resonator works in principle as a Spring-mass oscillator, wherein the spring by the resonator volume caged gas volume is formed while the Mass formed by the gas volume contained in the resonator throat is.

A typical Helmholtz resonator is usually so attached to the gas-carrying line that the resonator neck protrudes transversely from the line and so the side of the line arranged resonator volume connects to the line. at lower frequencies / frequency bands is a comparatively large resonator volume required, resulting in for the Resonator overall gives a comparatively large space. In a variety of applications, especially at an internal combustion engine, especially if this in one Motor vehicle is arranged, there is a shortage regularly in installation space, which makes the use of such resonators difficult.

The present invention deals with the problem for a resonator of the type mentioned an improved Embodiment, which in particular simplifies build the resonator compact.

This problem is inventively achieved by the subject matter of independent claim solved. Advantageous embodiments are the subject of the dependent claims.

The present invention is based on the general idea the resonator neck so that he along Although its longitudinal direction has a constant internal cross-sectional area has, however, a varying internal cross-sectional geometry having. In this construction, it is easy possible, the resonator neck with respect to its internal cross-sectional geometry adapt to almost any installation situation, while the constant internal cross-sectional area for it ensures that the resonator neck despite varying internal cross-sectional area its function essentially undisturbed can fulfill. This makes it possible in particular, the Resonator neck to adapt to cramped installation conditions, so he at a suitable location to the resonator volume is connectable and in terms of position and arrangement relative to the conduit due to the flexible shape of the Resonator neck significantly better on the existing installation conditions is customizable. Overall, therefore, a special compact resonator can be realized, in which the arrangement and shaping of resonator volume and resonator neck depending on the respective installation situation individually can be designed.

The present invention uses the knowledge that the resonator neck functions as a "mass" in the spring-mass vibration system regardless of the course of the internal cross-sectional geometry along its longitudinal direction substantially can fully maintain as long as along its longitudinal direction, the inner cross-sectional area of the Resonatorhalses is kept constant. The teaching of the invention for the design of the resonator neck means in practice a huge simplification for the design or adaptation of the resonator to individual installation situations and applications. In particular, there are considerable simplifications for the calculation of the resonance frequency or the Resonant frequency bands of the resonator, as with a constant Internal cross-sectional area can be expected. this makes possible particularly realistic calculations of the mode of action of the respective resonator. Varying internal cross-sectional geometries lead in conjunction with varying internal cross-sectional areas to complex interactions that an exact calculation of the effect of the respective resonator difficult or with the resources currently available make it almost impossible. The invention has recognized that the influences of a variable internal cross-sectional geometry on the Resonatorwirkung only a reduced influence have, if the inner cross-sectional area along the Longitudinal direction of the resonator remains constant. In that regard, can the calculations of the resonator effect for the interpretation of the respective resonator are considerably simplified. simultaneously the calculations agree with the realizable ones Resonator effects match much better.

Of particular advantage is an embodiment in which the resonator neck in its longitudinal direction at least partially extending along the outside of the conduit. On this way, the resonator hardly builds up across the line, so that only little space is needed in this direction. Advantageously, in a development, a section of Outside of the conduit part of a wall of the Resonatorhalses form, wherein this wall is the inner cross section the resonator neck along its longitudinal direction transverse to Limited longitudinal direction of the Resonatorhalses. In other words, the outside of the pipe is partly for training the resonator neck used, which on the one hand increased Functionality achieved for the outside of the pipe while on the other hand by this measure the compact Construction of the resonator neck is supported, as a Wandungsabschnitt in the area of the co-used outside section can be omitted.

A part of the wall of the resonator neck can in a further development be formed by a shell with to the line protruding outer edges to the outside of the line attached and attached to it. Such a shell Can be easily made and attached to the pipe become. Furthermore, with the help of such Shell the resonator neck particularly easy to the geometry adapted to the line, which is a particularly compact Construction supported.

According to an expedient embodiment, the resonator volume be formed in a housing which the line in a longitudinal section wrapped. The resonator neck is then inside arranged this case and connects the line within this housing with the resonator volume. With others Words, the housing envelops both a section of the Line as well as the resonator neck and encloses moreover the resonator volume. This construction also uses cleverly the available space for the formation of the resonator. In this embodiment, it was simultaneously recognized that the position in which the resonator neck with the resonator volume communicates within the resonator volume almost freely selectable.

Further important features and advantages of the invention result from the subclaims, from the drawings and from the associated figure description with reference to the drawings.

It is understood that the above and the hereinafter to be explained features not only in the each specified combination, but also in others Combinations or alone, without to leave the scope of the present invention.

A preferred embodiment of the invention is in the Drawings are shown in the description below explained in more detail, wherein the same reference numerals to identical or functionally identical or similar components Respectively.

Fig. 1

einen Längsschnitt durch einen erfindungsgemäßen Resonator,

Fig. 2

eine Draufsicht auf den Resonator entsprechend einem Pfeil II in Fig. 1, und

Fig. 3

eine perspektivische Ansicht auf einen Resonatorhals des Resonators der Fig. 1 und 2.

Show, in each case schematically,

Fig. 1

a longitudinal section through a resonator according to the invention,

Fig. 2

a plan view of the resonator according to an arrow II in Fig. 1, and

Fig. 3

a perspective view of a resonator neck of the resonator of Figs. 1 and 2.

According to FIG. 1, a resonator according to the invention has 1 a housing 2, which here assembled from two half-shells 3 and 4 is. The housing 2 envelops the one here shown longitudinal section of a line 5, the gas guide serves. On the other hand, the housing 2 encloses a resonator volume 6, wherein this resonator volume 6 thus between a Inside 7 of the housing 2 and an outside 8 of the line is trained. Accordingly, the resonator volume envelops 6 also the longitudinal section of the line shown here 5th

The resonator 1 is also equipped with a resonator neck 9, the one communicating link between the Resonator volume 6 and the line 5 and an interior 10th the line 5 creates. According to the invention, this resonator neck 9 now designed so that he along his, through a dashed line represented longitudinal direction 11th a constant internal cross-sectional area and a varying Internal cross-sectional geometry has.

In the gas-carrying line 5 is at the here shown embodiment to a part of an otherwise not shown exhaust system of an internal combustion engine, which may be arranged in particular in a motor vehicle can. Likewise, it may be at the line 5 to a component act a suction of the internal combustion engine or any other gas-carrying line, in which can spread airborne noise during operation. Furthermore It can also be at the line 5 to any other act gas-carrying line in which simultaneously in operation Airborne noise spreads; for example, in a turbine, a compressor, a pump, a blower or a another machine.

The airborne sound propagating in the line 5 is over decoupled from the resonator neck 9 and can thereby be treated especially damped or otherwise affected become. A main application is the damping a predetermined frequency or a predetermined frequency band, so that the resonator 1 works as a muffler. Likewise, it is basically possible, the resonator 1 so to design that the sound of the in line 5 changed airborne sound in a desired manner is called, "Sound Design". As a rule, this forms Resonator volume 6 together with the resonator neck 9 a oscillatory system in the manner of a spring-mass oscillator, so that the resonator 1 forms a Helmholtz resonator. Such a Helmholtz resonator 1 can be targeted to Attenuation of a certain frequency or a certain Frequency bands can be designed and then this frequency or effectively attenuate this frequency band.

The construction specification according to the invention, according to which the resonator neck 9 along its longitudinal direction 11 quasi arbitrary may have varying internal cross-sectional geometries, as long as the inner cross-sectional area along the longitudinal direction 11 remains substantially constant, it allows the resonator 1 very compact build. For example it is thereby possible, the resonator neck 9 as shown here To arrange the embodiment so that it is in his Longitudinal direction 11 partially or completely along the Outside 8 of the line 5 extends. In other words, the spatial course of the resonator neck 9 is on the outer contour the line 5 adapted. This adjustment takes place under the proviso that the inner cross-sectional area of the resonator neck 9 along its longitudinal direction 11 is constant remains.

In the embodiment shown here is for training the resonator neck 9 a shell 12 is used, the one Part of a wall 13 of the resonator neck 9 forms. These Wall 13 defines or limits the internal cross section of the Resonator neck 9 along the longitudinal direction 11 of the Resonatorhalses 9 transversely to the longitudinal direction 11 of the resonator neck. 9 The shell 12 has two lateral outer edges 14, from which only one is visible in the section of FIG. 1. These Outer edges 14 are from the rest of the shell 12 to 5 line down. The outer edges 14 are on the outer contour of the line 5, thereby enabling the shell 12 at its outer edges 14 to the outside 8 of the conduit fifth to be set. The shell 12 is attached to the conduit 5.

The connection of the shell 12 on the line 5 is expedient along the outer edges 14, for example by means of a corresponding weld. The shell 12 is for guidance 5 open. This has the consequence that another part the wall 13 of the resonator neck 9 through a section 15 of the outside 8 of the line 5 is formed. In this Section 15 of the outside 8 is the case covered by the shell 12 within the outer edges 14 Outside section 15.

In another embodiment, such Shell 12 are dispensed with. There will then be the relevant Section of the wall 13 e.g. by a suitable shaping of the housing 2 and the respective half-shell 3 or 4 educated. In other words, the contouring of the housing 2 or the respective half-shell 3 or 4 is carried out so the inner side 7 in a resonator neck 9 associated section directly a section of the wall 13th of the resonator neck 9 forms. In this case, the housing 2 on its inner side 7 to the outside 8 of the line fifth extend, so touch this. The wall 13 of the resonator neck 9 can then only through the outer side section 15 of the line 5 and by a corresponding Section of the inside 7 of the housing 2 are formed. Alternatively, it is also possible between the housing 2 and the line 5 at least insert a bridge, each from the inside 7 of the housing 2 to the outside 8 of the line 5 extends, ie to the inside 7 and the outside 8 connects. This bridge or the respective The bridge then forms a lateral boundary of the resonator neck 9. A Resonatorhals 9 facing side of the respective Stegs forms a section of the wall 13. A Such web can, for example, in a plan view accordingly Fig. 2 have a U-shape and can then substantially the outer edges 14 projecting towards the conduit 5 correspond to the shell 12. Such an embodiment, in which the housing 2 indirectly via at least one such web or is directly connected to the line 5, can then be used when between line 5 and the housing 2 similar temperatures or similar thermal expansions occur. In particular, the embodiment, in which the housing 2 is connected directly to the line 5 and thus manages without shell 12 and without webs, can be to produce very cheaply.

In the embodiment shown here, the resonator neck 9 at one end with respect to its longitudinal direction 11 transversely or laterally connected to the line 5. A connection opening 16, via which the resonator neck 9 with the interior 10 of the line 5 communicates, is thus laterally or transversely arranged to the longitudinal direction 11 on the resonator neck 9. The connection opening 16 thus creates a connection between the resonator neck 9 and the line 5, with respect to a indicated by an arrow flow direction 18 of the line 5 is arranged transversely or laterally. The connection opening 16 or the volumes communicating therewith in the resonator neck 9 and in the housing 2 thus have substantially no influence on the gas flow in the line 5.

Furthermore, the resonator neck 9 opens at the other end in his Longitudinal direction 11 in the resonator 6 a. That means, that a corresponding connection opening 17 substantially lies in a plane that is perpendicular to the section the longitudinal direction 11 extends through this connection opening 17 runs.

In Fig. 2 is for better representability to the viewer facing half-shell 3 omitted. According to FIG. 2 can the line 5 at least two sub-lines 19, 20, 21, 22, which communicate with each other in a node 23. For example, the internal combustion engine has two separate Exhaust strands, which are separated by separate sub-lines, z. B. via the partial lines 19, 20, the resonator 1 is supplied become. In node 23, the two sub-lines 19, 20 or the two exhaust lines communicating with each other connected, so that a single resonator 1 is sufficient to a certain frequency / a specific frequency band within the exhaust system to dampen simultaneously in both exhaust lines. After the resonator 1, the two exhaust lines again in two separate sub-lines, for example in the sub-lines 21 and 22, continued. This results For the exhaust system in the region of the resonator 1 is an X-shape. It is noteworthy that the housing 2 is the node 23 enveloped. Furthermore, the resonator neck 9 is at this Node 23 connected. That means the connection opening 16 is formed in the node 23.

As can be seen from Fig. 2, is by the leadership of the Sub-lines 19, 20, 21, 22 each between two sub-lines 19, 20 and 21, 22 a gap 24 and 25, respectively. In the embodiment shown here is now the between the two partial lines 21 shown on the left in FIG. 2, 22 formed gap 25 for accommodating the Resonatorhalses 9 used. Accordingly, the resonator neck extends 9 at least partially in this gap 25. By this skilful exploitation of the already existing space can the resonator neck 9 are designed so that it transversely to the Longitudinal direction or flow direction 18 of the conduit 5 only requires little space, which is particularly clear from FIG. 1 emerge. Accordingly, the housing 2 of the resonator 1 are designed extremely flat. This means in the present context "flat" that a longitudinal dimension 26 of the housing 2 is larger than a width dimension 27 and a height dimension 28. In the embodiment shown here is the length 26 about twice as large as the Width 27, while the width 27 is about twice as large as the height 28. In particular, the top view of FIG. 2 illustrates that the resonator 1 according to the invention only slightly requires more installation space than the exhaust system in Area of the node 23. It is noteworthy that in Housing 2 a relatively large resonator volume 6 included is, so that with the help of the resonator 1 in particular can also attenuate lower frequencies or frequency bands.

The embodiment shown here shows that it is the inventive Design regulation for the resonator neck 9 allows the resonator neck 9 and thus the entire resonator 1 optimally adapted to the existing installation space, wherein the existing installation space in particular any can have three-dimensional contour. This allows existing spaces are optimally used.

3 shows a perspective view of the resonator neck 9 of the embodiment according to FIGS. 1 and 2. In this case the visible part of the shell 12 with a solid line while a portion 29 of the resonator neck 9 shown by the broken line through the outer side portion 15 of the line 5 is limited. Furthermore are within the Resonatorhalses 9 exemplarily seven inner cross-sections 30a to 30g marked with broken lines and next to it, ie outside the resonator neck 9 again shown by solid lines. in this connection is easily recognizable that the individual inner cross sections 30a to 30g along the longitudinal direction 11 of the resonator neck 9 clearly different internal cross-sectional geometries possess, with their associated internal cross-sectional areas according to the invention are the same.

The variant shown here is only an example and clarifies like the design rule according to the invention the adaptation the resonator neck 9 and thus the resonator housing 2 to any available installation space with almost any three-dimensional shape, to thereby for the entire resonator 1 a compact, adapted to the respective mounting situation design to achieve.

Claims (15)

Resonator for the treatment of airborne sound, which propagates in a gas-carrying line (5), with a resonator neck (9) which communicates the line (5) with a resonator volume (6), wherein the resonator neck (9) has a constant internal cross-sectional area along its longitudinal direction (11), wherein the resonator neck (9) along its longitudinal direction (11) has a varying internal cross-sectional geometry. Resonator according to claim 1,
characterized in that the resonator neck (9) extends in its longitudinal direction (11) at least partially along an outer side (8) of the conduit (5), Resonator according to claim 1 or 2,
characterized in that a section (15) of an outer side (8) of the conduit (5) forms part of a wall (13) of the resonator neck (9), which forms the inner cross section (30) of the resonator neck (9) along its longitudinal direction (11). bounded transversely to the longitudinal direction (11) of the resonator neck (9). Resonator according to claim 3,
characterized in that a part of the wall (13) of the Resonatorhalses (9) by a shell (12) is formed, which attached to the line (5) projecting outer edges (14) to the outside (8) of the line (5) and attached to it. Resonator according to one of claims 1 to 4,
characterized in that the resonator neck (9) with respect to its longitudinal direction (11) is connected transversely or laterally to the conduit (5). Resonator according to one of claims 1 to 5,
characterized in that the resonator neck (9) is connected in its longitudinal direction (11) to the resonator volume (6). Resonator according to one of claims 1 to 6,
characterized, in that the resonator volume (6) is formed in a housing (2) enclosing the line (5) in a longitudinal section, in that the resonator neck (9) is arranged inside the housing (2) and connects the line (5) to the resonator volume (6). Resonator according to claim 7,
characterized in that a portion of an inner side (7) of the housing (2) forms part of a wall (13) of the resonator neck (9), which cross section the inner cross section (39) of the Resonatorhalses (9) along its longitudinal direction (11) transversely to the longitudinal direction (11) of the resonator neck (9) limited. Resonator according to claims 3 and 8,
characterized, in that at least one web is provided, which extends from the inside (7) of the housing (2) to the outside (8) of the conduit (5) and at a side facing the resonator neck (9) has a portion of the wall (13). the resonator neck (9) forms, or that the wall (13) of the Resonatorhalses (9) of the housing (2) and the portion (15) of the outer side (8) of the conduit (5) is formed exclusively by the portion of the inside (7). Resonator according to one of claims 1 to 9,
characterized, that the pipe (5) at least two part lines (19, 20, 21, 22), which communicate with each other in a node (23), that the resonator neck (9) is connected to the node (23). Resonator according to claim 10,
characterized in that the resonator neck (9) extends in a gap (25) formed at the node (23) between two sub-lines (21, 22). Resonator according to claim 7 and according to claim 10 or 11,
characterized in that the housing (2) surrounds the node (23). Resonator at least according to claim 7,
characterized in that the housing (2) is flat. Resonator at least according to claim 7,
characterized in that the connection between the resonator neck (9) and line (5) with respect to the flow direction (18) in the conduit (5) is arranged laterally or transversely. Resonator according to one of claims 1 to 14,
characterized in that the gas-carrying line (5) is a component of an exhaust system of an internal combustion engine, in particular in a motor vehicle.

Images