WO2008015046A1

WO2008015046A1 - Apparatus for sound absorbing in a tubular channel

Info

Publication number: WO2008015046A1
Application number: PCT/EP2007/055641
Authority: WO
Inventors: Peter Marschall
Original assignee: Contitech Kühner Gmbh & Cie.Kg
Priority date: 2006-08-01
Filing date: 2007-06-08
Publication date: 2008-02-07
Also published as: DE102006035755A1; EP2049776A1

Abstract

The invention relates to an apparatus for absorbing the sound of a medium which flows through a tubular channel, has pulsating pressure differentials and has, at least in sections, a proportion which rotates about the longitudinal axis of the tubular channel, wherein the rotational speed of the medium is proportional, from the centre of the rotation radially to the outside, to the radial spacing from the rotational centre, characterized in that the tubular channel has at least two tubular-channel sections (1, 2) 15, wherein the first tubular-channel section (1) is arranged ahead of the second tubular-channel section (2) in the flow direction and the first tubular-channel section (1) has a predefined flow cross-sectional area (8) which is greater than the flow cross-sectional area (11) of the second tubular-channel section (2), and the ratio of the flow cross-sectional area (8) of the first tubular-channel section (1) and the flow cross-sectional area (11) of the second tubular-channel section (2) is selected in such a way that, during the passage from the first tubular-channel section (1) into the second tubular-channel section (2), the rotating medium can be accelerated in the rotational direction proportionally to the rotational speed and in the process the axial speed of the rotating medium can be reduced proportionally to the rotational acceleration of the medium.

Description

Device for sound damping in a pipe duct

description

The invention relates to a device for sound attenuation of a flowing through a pipe channel, pulsating pressure density differences and at least partially having a rotating about the longitudinal axis of the pipe channel share medium, wherein the rotational speed of the medium from the center of rotation radially outward to the radial distance from the center of rotation is proportional.

Such devices are used for example in exhaust pipes of internal combustion engines or air conditioning lines of automotive air conditioning. By pulsating pressure generation arise in such systems oscillations in the medium, which cause pressure density differences and make themselves felt as unwanted noise emissions. By swirling elements, such as vanes or coiled tubes while at least a portion of the medium is forced to cover a longer path in the pipe channel than the rest, not or rotating at a lower rotational speed part of the medium. As a result, waves and valleys of the pressure density differences are shifted from each other during the interaction of the parts of the medium. The resulting superposition vibration is smoothed compared to the original vibration, which reduces the noise emission.

Such devices are known, for example, from DE 103 281 44 A1 or DE 101 63 812 A1. A disadvantage of these solutions, however, is that the effects of the devices are very difficult to predict and interpret in advance and therefore must be determined in practice for each system by experiments. The invention has for its object to provide a device of the type described, which effectively attenuates the sound emissions at different vibration ratios even without complex individual adjustments.

This object is achieved in that the tube channel has at least two tube channel sections, wherein the first tube channel section is arranged upstream of the second tube channel section and the first tube channel section has a predetermined flow cross-sectional area which is larger than the flow cross-sectional area of the second tube channel section and the ratio of flow cross-sectional area of first tube channel portion and flow cross-sectional area of the second tube channel portion is selected so that the rotating medium in the transition from the first tube channel portion in the second tube channel portion in the direction of rotation can be accelerated proportional to the rotational speed and while the axial velocity of the rotating medium is reduced proportional to the rotational acceleration of the medium.

When the rotating medium exits the first tube channel section, it has a certain rotation momentum. Apart from low friction losses, which occur at the wall of the pipe channel, after the spin set of the mechanics, the angular momentum also remains at the transition of the medium into the smaller flow cross-sectional area. This has the consequence that the angular velocity of the rotating medium increases, the medium thus accelerated in the direction of rotation.

The medium is decelerated in the axial direction during this change in the rotational speed of the Coriolis acceleration, since the Coriolis acceleration acts perpendicular to the direction of movement of the medium. Thus, the Coriolis acceleration generates a force which is also effective in the axial direction, the amount of energy required by this force along the path of the medium during the transition into the smaller flow cross-sectional area being removed from the axial kinetic energy of the medium, ie the medium in the axial direction is slowed down. The Coriolis acceleration is also dependent on the rotational speed of the medium, so that the braking effect is greatest on the areas of the medium which are most strongly accelerated during the transition from the first flow cross-sectional area to the second flow cross-sectional area.

The axial velocity of the medium thus decreases continuously from the center of the tube channel to the most strongly rotating regions on the inner wall of the tube channel.

The above-described effect that by the displacement of the pressure density differences across the flow cross-section amplitude maxima and amplitude minima balanced against each other and thereby the sound emissions are reduced, so the device of the invention is still to improve, with a special calculation is not required.

In a further development of the invention, in the first pipe channel section, swirling bodies are arranged with an inflow end and an outflow end, by means of which the rotation of the medium can be influenced.

If, for example, the rotation of the medium flowing through the first pipe channel section is insufficient during the transition into the second pipe channel section in order to achieve the desired effect, the rotation of the medium can be increased with said swirling bodies.

In a further development of the invention, the outflow ends of the swirling body are spaced from the transition from the first pipe channel section to the second pipe channel section by a predetermined amount.

About such a distance, the rotational acceleration and associated axial delay of the medium can be influenced. At a large distance, the acceleration smaller, larger at a small distance. For a simple fine tuning of the device is possible.

In a further embodiment of the invention, the swirl bodies are coiled vanes which are arranged twisted about the central axis of the pipe channel section and which are fixedly and permanently attached to a coaxial pipe to the vanes and form a swirl insert with the pipe inside the first pipe - Channel section is arranged coaxially with the pipe channel.

In a further development of the invention, the swirling insert is a profile section produced in the extrusion process.

In a development of the invention, the swirling insert is a plastic injection-molded part.

The geometry of the swirling insert according to the invention allows a simple and secure installation in the pipe channel. In addition, a swirling insert designed in this way can be produced cost-effectively in the aforementioned ways.

In a further embodiment of the invention, the swirl bodies are formed by radially inwardly directed axially coiled projections of the wall of the first pipe channel section, which have a predetermined length and pitch matched to the first pipe channel section and the transition region.

Such projections can be produced for example by plastic deformation of the pipe channel wall. As a result, no separate use is necessary.

In a further embodiment of the invention, the first flow cross-sectional area in the first tube channel section is greater than the flow cross-sectional area of a third, to the first tube channel section in the flow direction of the medium before the first

Pipe duct section arranged pipe duct section, wherein the transition from the Strö- mung cross-sectional area of the third tube channel portion in the flow cross-sectional area of the first tube channel portion of the said third tube channel portion associated end of the swirl body is spaced by a predetermined amount.

The Verwirbelungskörper reduce the free flow cross-sectional area by the extent of their end faces, so that it can come to a dynamic pressure and thus to an undesirable reduction of the flow velocity when the medium impinges on the turbulence body. The expansion volume formed by the arrangement according to the invention in front of the turbulence bodies allows the medium to distribute the dynamic pressure to the end faces of the turbulence bodies. As a result, the flow resistance in the first tube channel section is reduced again.

In a further embodiment of the invention, the first tube channel section is formed by a widening process from the tube channel.

The expansion, for example by hydroforming or thorns, has the advantage that no additional material for the increased diameter is required.

In a further development of the invention, the diameter of the second tube channel section is reduced by pulling it in relation to the diameter of the first tube channel section.

Retraction has the advantage that no thermal joining methods have to be used.

In a development of the invention, the turbulence insert is fixed by a press fit in the first tube channel section.

By pressing the Verwirbelungseinsatzes a thermal connection or sticking of the insert is not required. The subsequent retraction of the second pipe channel section secures the Verwirbelungseinsatz additionally. The solution according to the invention provides a cost-effective, easy-to-install and effective device for sound damping in pipe ducts, with which the sound emission of any pulsed flow can be reduced. Previous trial phases or complex calculations can be reduced or completely eliminated.

With reference to the drawing, an example of the invention will be explained in more detail below. It shows:

1 shows a longitudinal section through a pipe channel section with the device according to the invention,

Fig. 2 is a symbolic diagram of the velocity distribution of the medium flowing through the device according to the invention and

3 shows the achievable by the velocity distribution reduction of vibration amplitudes of the flowing medium based on amplitude envelopes

FIG. 1 shows a part of a pipe channel with a first pipe channel section 1, a second pipe channel section 2 and a third pipe channel section 3 in longitudinal section. A medium, not shown, flows through the three tube channel sections 1, 2, 3 first through the tube channel section 3, then through the tube channel section 1 and then through the tube channel section 2.

Inside the tube channel section 1, a turbulence insert 4 is arranged coaxially with the tube channel section 1. The turbulence insert 4 has a tubular central element 5, on whose outer surfaces uniformly distributed on the circumference of the central element 5 three vanes 6 are arranged. The vanes 6 are helically coiled and insoluble and firmly connected to the central element 5. The turbulence insert has an axial end face 7.

The outer diameter of the swirling insert 4 is dimensioned so that it can be pressed into the inner diameter of the tubular channel section 1 with a press fit. The interference fit ensures a tight fit of the swirling body 4 in the pipe channel 1 Part of the medium, not shown, flows through the swirling insert 4 through the tube 5 and the remaining part of the medium, not shown, flows around the outside of the tube 5 and is set in rotation by the guide vanes 6. The pipe channel section 1 has a flow cross-sectional area 8, wherein in the figure, for better clarity, the corresponding diameters are shown as equivalent to the flow cross-sectional areas. The pipe channel section 3 has a flow cross-sectional area 9, the flow cross-sectional area 9 being approximately as large as the flow cross-sectional area 7, reduced around the end face 7 of the swirling body 4. The flow cross-sectional area effective for the medium is therefore approximately as large in the pipe channel section 1 as in the pipe channel section 3.

At a predetermined distance from the end of the swirling element 4 associated with the pipe channel section 2, the pipe channel has a transitional region 10, in which the pipe channel section 1 merges with the flow cross-sectional surface 8 into the pipe channel section 2 with a flow cross-sectional surface 11. The rotating part of the medium, not shown, undergoes an increase in its rotational angular velocity in the transition region 10 due to the spin set of the mechanism, while at the same time reducing its axial velocity caused by the Coriolis effect.

The non-rotating part does not experience this acceleration.

In FIG. 2, the effects of said accelerations are shown symbolically by selected oscillation amplitudes 12 to 16 and speed arrows 17. The oscillation amplitudes 12 to 16 each represent a selected instantaneous axial position of the flowing medium, the oscillation amplitude 12 representing the state of the medium in the flow direction before entering the region of the turbulizer 4. The oscillation amplitude 13 represents the state after the medium has entered the region of the tube channel section 1 with the diameter 7, the oscillation amplitude 14 after the medium impinges on the turbulence body 4, the oscillation amplitude 15 immediately after leaving the region of the turbulence. 4 and the vibration amplitude 16 after flowing through the transition region 10.

The arrow drawn furthest down in each oscillation amplitude 12 to 16 represents the axial velocity in the center of the flow, the upper one the axial velocity of the medium in the edge region of the tube channel section 1. At the oscillation amplitude 12, all regions of the medium flow with approximately the same axial velocity Speed. At the oscillation amplitude 13, all regions of the medium likewise flow at approximately the same axial velocity. However, the oscillation amplitude 13 is slightly attenuated because of the larger diameter 7 at this point of the pipe channel section 1. At the oscillation amplitude 14, after the impact of the medium on the turbulence body 4, the medium begins to rotate increasingly from the inside to the outside. As a result, the axial velocity continuously decreases from the center of the flow to the edge of the flow, which is made clear by the staggered position of the arrow 17 relative to one another. The lowest arrow represents the velocity of the non-rotating medium in the center of the flow. As a result of the increasing rotational speed of the medium along the flow around the swirling body 4, the axial velocity of the medium continues to decrease toward the outside, which becomes clear at the oscillation amplitude 15. In the case of the oscillation amplitude 16, the Coriolis effect additionally comes into play, which further slows down the axial velocity of the medium after flowing through the transitional region 10 of the tubular duct section 1.

FIG. 3 shows the effects of the speed changes from FIG. 2 on the amplitudes of the oscillations on the basis of five amplitude envelopes 18 to 22, wherein the envelope 18 is assigned to the oscillation amplitude 12 from FIG. 2 and the envelopes 19 to 22 are continuously assigned to the oscillation amplitudes 13 to 17 are assigned from Fig. 2. Due to the decreasing axial velocity of the rotating medium over the flow path along the swirling body 4 and through the transitional region 10, a displacement of the respective amplitude maxima results, so that with the enveloping curve 22 at the end of said flow path a particularly well smoothed vibration is obtained. yielding curve. This leads to a significant lowering of the sound level in the pipe channel section. 1

LIST OF REFERENCE NUMBERS

(Part of the description)

1 first pipe channel section

2 second pipe channel section

3 third pipe channel section

4 swirling operation

5 central element 6 vanes

7 end face of the swirling insert 4

8 flow cross-sectional area of the first tube channel section. 1

9 flow cross-sectional area of the third tube channel section 3rd

10 transition area 11 flow cross-sectional area of the second tube channel section 2 12 - 16 oscillation amplitudes

17 speed arrows

18 - 22 amplitude envelopes

Claims

claims

1. A device for sound attenuation of a flowing through a pipe channel, pulsating pressure density differences and having at least partially a rotating about the longitudinal axis of the pipe channel share medium, wherein the

Rotational speed of the medium from the center of the rotation radially outward to the radial distance from the center of rotation is proportional, characterized in that the tube channel has at least two tube channel sections (1, 2), wherein the first tube channel section (1) upstream of the second tube channel section (2) and the first tube channel section (1) has a predetermined flow cross-sectional area (8) that is greater than the flow cross-sectional area (11) of the second tube channel section (2) and the ratio of flow cross-sectional area (8) of the first tube channel section (1) and flow cross-sectional area (FIG. 11) of the second tube channel section (2) is selected so that the rotating medium during the transition from the first tube channel section (1) in the second tube channel section (2) in the direction of rotation can be accelerated in proportion to the rotational speed, while the axial velocity of the rotating medium proportion al is reducible to the rotational acceleration of the medium.

2. Apparatus according to claim 1, characterized in that in the first pipe channel section (1) swirling body (6) are arranged, through which the rotation of the medium can be influenced.

3. Apparatus according to claim 2, characterized in that the outflow ends of the Verwirbelungskörper (6) from the transition (10) from the first tube channel portion (1) to the second tube channel portion (2) are spaced by a predetermined amount.

4. Apparatus according to claim 2 or 3, characterized in that the Verwirbelungskörper (6) are coiled guide vanes, which are arranged around the central axis of the Rohrkanal- section (1) twisted and on a to the guide vanes (6) coaxial tube (5 ) are firmly and permanently attached and connected to the tube (5). form swirl insert (4), which is disposed within the first pipe channel portion (1) coaxial with the pipe channel.

5. Apparatus according to claim 4, characterized in that the Verwirbelungseinsatz (4) is a profile section produced in the extrusion process.

6. Apparatus according to claim 4, characterized in that the Verwirbelungseinsatz (4) is a plastic injection molded part.

7. The device according to claim 2 or 3, characterized in that the Verwirbe- lungskörper (6) by radially inwardly facing, coiled in the axial direction projections of the wall of the first tube channel portion (1) are formed, which have a predetermined length and pitch.

8. Device according to at least one of the preceding claims, characterized in that the first flow cross-sectional area (8) in the first tube channel section

(1) is larger than the flow cross-sectional area (9) of a third tube channel portion (3), wherein the transition from the flow cross-sectional area (9) of the third tube channel portion (3) in the flow cross-sectional area (8) of the first tube channel portion (1) of the third end of the swirling body (6) is spaced by a predetermined amount.

9. Device according to at least one of the preceding claims, characterized in that the first tube channel section (1) is formed by a widening process from the tube channel.

10. The device according to at least one of the preceding claims, characterized in that the flow cross-sectional area (11) of the second pipe channel section

(2) is reduced by drawing the first tube channel section (1) with respect to the flow cross-sectional area (8) of the first tube channel section (1).

11. The device according to at least one of the preceding claims, characterized in that the Verwirbelungseinsatz (4) is fixed by a press fit in the first tube channel section (1).