SE523018C2 - Muffler and use of said muffler in an exhaust system for an internal combustion engine - Google Patents

Abstract

A silencer is provided that is intended to be connected to a gas flow with pressure fluctuations, such as for example downstream a combustion engine, the silencer comprising a housing provided with an envelope surface and two side surfaces and an inlet opening and an outlet opening arranged in the envelope surface.

Description

25 4.30 ones:,. An object of the invention is to provide a muffler with low back pressure and good sound-absorbing ability, which muffler is cheap to manufacture. This object is achieved by a muffler according to the characterizing part of the patent claim. A sound fl through a channel can be seen as a series of pressure rises with intermediate pressure drops that travel one after the other through the channel. side and a set of outlet ducts on the other side of the dividing wall, a countercurrent fate occurs on opposite sides of the dividing wall.

Pressure increases and pressure decreases will then pass each other at regular intervals in time and space. Since the wall is partly resilient due to its folded construction, pressure differences on both sides will be equalized, whereby damping is achieved. Thus, each time a pressure shock passes a pressure wave, both will decrease in amplitude. In a preferred embodiment, the damping can be further increased by damping the movement of the partition wall by friction. Furthermore, perforations in the partition wall can be arranged, whereby pressure pulsations through these perforations can further improve the sound attenuation ability.

In a particularly preferred embodiment, the separating wall between the inlet opening and the outlet opening is arranged, in such a way that it extends between turning chambers, arranged in connection with the side walls of the muffler, and has a set of inlet channels which lead from the inlet opening to said opening said turning chamber to the outlet opening, the separating wall dividing the flow into two substantially opposite flow paths from the inlet opening via the turning chamber and which flow paths meet at the outlet opening. This construction gives rise to a muffler where the opposite flow paths give rise to very good sound-absorbing ability. In addition, each of these flow paths is characterized by the flow in a reciprocating path with countercurrent flow on each side of the partition wall.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be described in more detail in connection with the accompanying drawing figures, in which Fig. 1 shows a manufacturing method for a muffler according to the invention, fi g. 2 shows the muffler in detail, with an indication of flow paths through the muffler, and fi g. 3 shows in detail surfaces of the partition wall according to an embodiment of the invention.

DETAILED DESCRIPTION OF THE INVENTION Figure 1 shows the manufacture of a muffler according to the invention. A partition 1b included in the muffler is formed by a metal strip 1a which is formed by pressing, rolling or the like. The metal strip is further formed in a pressing step between rollers where the metal strip 1a is partly given a surface structure 20, which is shown in enlargement in Figure 1, and partly a set of mutually directed bending instructions 2, 3. The partition wall is thus formed by a strip to a package which forms a set of inlet ducts on one side of the partition wall and a set of outlet ducts on the other side of the partition wall.

The surface structure of the metal strip has a set of projections which are arranged which, when the metal strip is folded and has a set of inlet channels and outlet channels, cause increased turbulence to occur during flow through the channels in the partition, forming flow paths as explained below. In a preferred embodiment of the invention, the projections consist of a corrugation obliquely across the belt, preferably angled 40 ° - 70 ° in relation to the direction of the bending instructions 2, 3. The projections also function as a spacer element and mean that a rigid construction is obtained even when the strip is made of thin material such as sheet metal with a thickness of less than 0.2 mm, preferably less than 0.1 mm. Materials with a thickness down to and below 0.05 mm can also be used with good results.

In a second manufacturing step, the metal strip 1a is folded together into a partition wall 1b which has a set of inlet ducts 21, one of which is shown in a folded position in Figure 2 and a set of inlet ducts 22. Furthermore, the partition wall 1b is provided with seals 5, 6 in each end portion of 30, 523 018 4 / the metal strip 1a, which seals are intended to abut against an upper and a lower surface 22, 23 of a casing 4 enclosing the partition wall 1b. Each of the inlet channels 21 is formed by an upper and a lower substantially flat surface 24, 25 and a fold 26 »which connects the upper and the lower surface. In the same way, each of the outlet channels 22 is formed by an upper and a lower substantially flat surface 27, 28 and a fold 29 which connects the upper and the lower surface.

Each of said set of inlet ducts and outlet ducts the channels are thus denoted by an upper and a lower substantially flat surface and a fold which connects said surfaces where the upper and the lower substantially flat surfaces are preferably formed substantially parallel.

The corrugations of nearby folds in the folded metal strip cross each other and cause the metal strip to form a stable and crunchy flour fi in a package with a large free volume when compressed.

Between the folds of the belt, flow channels with a stable geometry are formed. An advantage of the sound attenuation ability is that each of these channels, through the corrugations of the belt, forms a large number of irregular flow paths of different lengths. This causes the light waves that pass through the channels to split into many phase-shifted sub-waves that tend to extinguish each other. The design with crossed corrugations means that the number of sound paths and sound correction points becomes very large. Preferably, the belt is designed so that direct flow and transparency are avoided.

Furthermore, according to an embodiment of the invention, the partition wall can be designed with perforations, whereby pressure pulsations through the partition wall cause further sound attenuation.

In general, the partition divides the flow into two substantially opposite flow paths from the inlet opening via the reversing chamber and which flow paths meet at the outlet opening. By substantially opposite flow paths is meant that the average flow through the paths is opposite, whereby the use of projections, for example in the form of corrugations for generating a large number of flow paths within the respective opposite flow path, does not change the fact that the flow paths are substantially opposite.

In a preferred embodiment of the invention, the partition wall 1b is designed with such a geometry that each of the inlet and outlet ducts in said set of inlet and outlet ducts 21, 22 has an extension from a turning chamber 7 to a turning chamber 8, 523 018 f * 5 which substantially exceeds the extent from an inner fold edge 26 to an outer fold edge 29 of said inlet and outlet channels.

In a third manufacturing step, the partition wall 1b is placed in said casing 4, after which casing et is closed by fixing the upper surface 22.

The housing 4 has a jacket surface 30 and two side surfaces 31, 32. The jacket surface and the side surfaces together form a closed volume. Two opposite surfaces of the jacket surface are provided with an inlet opening 9 and an outlet opening 10. The placement of the partition wall 1b inside the housing is made so that the folds 29 of the outlet channels are placed against the side of the jacket surface 30 which has said inlet opening and the side 26 of the inlet opening the mantle surface 30 which has said outlet opening 10. In a preferred embodiment of the invention, the partition wall 1b is formed and covered with a rectangular cross-section, which means that the manufacturing process becomes efficient. In connection with said side surfaces 31, 32, two reversible cores 7, 8 are arranged. The reversing chambers allow an overflow from inlet ducts 21 to outlet ducts 22.

To allow effective sound attenuation, the partition wall is designed with at least 10 pairs of inlet ducts and outlet ducts. Furthermore, in a preferred embodiment, the dividing wall is designed so that the ratio between the extent from the turning chamber to the turning chamber and the extent from an inner folding edge where the belt is folded counterclockwise to an outer folding edge the belt is folded clockwise is between 1.1 and 6, preferably between 1.4 and 3. The channels further have such a design that the extension from the folds 26 of the inlet channel 21 facing the side of the housing 4 where the outlet opening 10 is arranged to the folds 29 of the outlet channel 22 facing the side of the housing 4 where the inlet opening 9 is arranged substantially exceeding the height from an upper channel wall to a lower channel wall. In a preferred embodiment, the ratio of height it from an upper channel wall to a lower channel wall and the extent from an inner fold to folds is between 1/30 and 1/100.

Figure 3 shows in detail the shape of the wall with the above-mentioned surface structure in the form of a corrugation obliquely across the strip, preferably angled 40 ° - 70 ° in relation to the direction of the bending instructions 2, 3. 00:00 10 15 523 018 6,. According to a preferred embodiment of the invention, the inlet opening and the outlet opening are symmetrically placed with respect to the partition wall, the flow path from the inlet opening to the outlet opening being the same regardless of which reversing chamber the flow takes place. In a further preferred embodiment, the inlet opening and the outlet opening are located opposite each other on opposite sides of the housing.

Figure 4 schematically shows an exhaust system for an internal combustion engine. The combustion engine has an inlet 35 and an exhaust manifold 36 which connects to said exhaust system. A first catalyst 37 is arranged downstream of the outlet ports of the internal combustion engine 33. A muffler according to the invention described above is mounted downstream of this catalyst.

The invention shall not be limited to the above-described exemplary embodiments, but may be varied within the scope of the appended claims, for example, the partition wall may be manufactured in another manufacturing method and the cross-section of the partition wall may have a different cross-section than rectangular

Claims (5)

A muffler intended to be connected to a gas med desert with pressure fluctuations such as, for example, downstream of an internal combustion engine, wherein the muffler comprises a housing (4) having an inlet opening (9) and an outlet opening (10), a partition wall (1) and a turning chamber (7, 8) where the flow is diverted from one side of the partition wall (1b) to the other, the partition wall (1b) dividing the flow into two substantially opposite flow paths on either side of the partition wall (1b), characterized in that the partition wall (1b) is formed by a band (1a) which is z-shaped folded into a package which forms a set of inlet channels (21) on one side of the partition (1b) and a set of outlet channels (22) on the other side of the partition (1b). A muffler according to claim 1, characterized in that the partition wall (lb) is resiliently designed, whereby pressure differences on both sides of the partition wall (lb) are reduced. Silencer according to Claim 2, characterized in that the partition wall (1b) has a thickness of less than 0.2 mm, preferably less than 0.1 mm. A muffler according to any one of claims 1 to 3, characterized in that each of the sets of inlet ducts (21) and outlet ducts (22) comprises an upper and a lower substantially flat surface (24-25, 27-28) and that the substantially planar surfaces (24-25, 27-28) are formed with a set of projections, which are arranged to generate a large number of irregular flow paths through each of the substantially opposite flow paths. Silencer according to Claim 4, characterized in that the projections have such an extent from the upper and lower flat surfaces (24-25, 27-28) included in the channels (21, 22) that transparency from one end to the opposite end of the channels (21 , 22) prevented. 10 523 018 8 0 nu u 0 I - u ø ø. ~ u Q. . A muffler according to any one of claims 1 to 5, characterized in that each of the sets of inlet ducts (21) and outlet ducts (22) is defined by an upper and a lower substantially flat surface (24-25, 27-28). ) and a fold (26, 29) which connects the surfaces and that the upper and lower substantially flat surfaces (24-25, 27-28) are substantially parallel. Silencer according to one of the preceding claims, characterized in that the partition wall (1b) forms at least 10 superimposed inlet and outlet channels (21, 22). A muffler according to any one of the preceding claims, wherein the package has a set of inner fold edges (26) where the belt is folded counterclockwise and a set of outer fold edges (29) where the belt is folded clockwise, characterized in that the extension from an inner fold edge (26) to an outer fold edge (29) of the inlet and outlet channels (21, 22) substantially exceeds the height from an upper channel wall to a lower channel wall. Silencer according to claim 8, characterized in that the ratio between the height from an upper channel wall to a lower channel wall and the extent from an inner folding edge (26) to an outer folding edge (29) is between 1/30 and 1/100. claim 1, wherein the pair of extensions comprises a housing (4) having a jacket surface (30) and two side surfaces (31, 32), wherein the inlet opening (9) and the outlet opening (10) are arranged in the jacket surface (30), characterized in that a first and a second turning chamber (7, 8) are arranged adjacent to the side surfaces (31, 32), and that the partition (1b) extends between the respective turning chambers (7, 8), the set of inlet channels (21) leading from the inlet opening (9) to the reversing chamber and the set of outlet channels (22) lead from the reversing chamber to the outlet opening (10), the partition wall (1b) dividing the flow into two substantially opposite flow paths from the inlet opening (9) via reversing core arms and which flow runways meet at the outlet opening (10). 11 12 13 14 15 523 o1a f? Silencer according to claim 10, characterized in that the ratio between the extent from the reversing chamber (7) to the reversing chamber (8) and the extent from an inner folding edge (26) to an outer folding edge (27) is between 1.1 and 6, preferably between 1, 4 and 3. A muffler according to any one of claims 10 or 11, characterized in that the inlet opening (9) and the outlet opening (10) are symmetrically located with respect to the partition wall (1b), the flow path from inlet opening (9) to outlet opening (10) being the same regardless of which reversing chamber (7, 8) the flow takes place. Silencer according to claim 12, characterized in that the inlet opening (9) and the outlet opening (10) are located midway between the edge regions of the partition wall (1b) which connect to the turntable frame (7, 8). Silencer according to one of the preceding claims, characterized in that the sliding wall (lb) has perforations. Use of a muffler according to any one of the preceding claims in an exhaust system for an internal combustion engine downstream of a first catalyst.