WO1998019054A1

WO1998019054A1 - Exhaust muff

Info

Publication number: WO1998019054A1
Application number: PCT/EP1997/006018
Authority: WO
Inventors: Burkhard Gelhar; Henrik Kluge; Dieter Lohmann
Original assignee: Deutsches Zentrum für Luft- und Raumfahrt e.V.
Priority date: 1996-10-31
Filing date: 1997-10-31
Publication date: 1998-05-07
Also published as: DE19644089A1; DE29723969U1

Abstract

Disclosed is an exhaust muff for combustion engines, comprising an exhaust gas duct (22, 23) in which spiral parts are arranged so as to damp the noise from the exhaust gas. Said duct (22, 23) is surrounded by a ring tube filled with gas.

Description

Silencer

The invention relates to a silencer for internal combustion engines.

Internal combustion engines are regularly equipped with silencers; this applies to motor vehicles, airplanes and other internal combustion engines. It is desirable to keep the generation of noise from the exhaust gas of the engine as low as possible. In known mufflers for internal combustion engines, discontinuous flow deflections, jumps in diameter and resistances are provided in the muffler duct in order to change the speed of the exhaust gas flowing through and thus achieve noise reductions. In the case of aircraft, a chamber (that is to say an enlarged diameter) is generally provided in the muffler and then a narrowing in the direction of flow.

It is problematic, among other things, that if the back pressure is formed in the exhaust pipe, that is to say in the muffler, a flow resistance associated therewith can have a performance-reducing effect on the engine. Additional installations also lead to disadvantageous weight increases in the overall system and thus - particularly evident in aircraft - to an increase in fuel consumption, ultimately also an increase in the amount of exhaust gas and, in turn, to an increase in noise generation that is in itself to be avoided.

From FR 1 149 456 a silencer device for engines, compressors etc. is known, which has a perforated outlet pipe that allows the passage of outlet gases and is arranged in an annular casing. The space between the outlet pipe and the casing is filled with a sound wave absorbing material. A helical or helical sheet is arranged in the outlet pipe, which forces the outlet gas to move in a helical manner, whereby it nestles very closely against the perforated wall of the outlet pipe. The exit movement is thus guided in the direction of the helical wall. CH 313 645 discloses a sound attenuation device with two coaxially arranged tubes within a housing. The tubes have perforated walls. A screw is inserted between the inner and outer tube, the inner tube being filled with a refractory fiber material. The exit gas therefore flows helically through the annular space created between the outer and inner tube, part of the gas penetrating into the layer of refractory material provided between the housing and the outer tube and another part into the fiber material in the inner tube. This expands the gas.

Such an embodiment with ring channel and screw is also apparent from FR 1 149 456.

In contrast, the object of the invention is to provide improved sound damping for internal combustion engines. This object is achieved in that helical internals are provided in the silencer duct, and in that the duct is surrounded by an outer ring duct, the outer ring duct being filled with a gas. Further developments of the invention are defined in the subclaims.

With such helical internals, noise reduction of the exhaust noise is achieved. The sound is reduced on the helical surfaces by reflection and scattering and then absorption in the channel wall and is also prevented from spreading due to the so-called cut-off effect.

Helical internals also have the advantage of creating helical channels, so that compared to silencer designs without a helix, the same volume can be accommodated in a smaller outer container. This not only saves material and makes the silencer lighter, it also has the other advantages of lower external volume.

The material saving is immediately apparent when one imagines that a section under consideration from both its front and back is used now, namely as a flow-facing surface in a screw thread and as a flow-away surface in the following. Due to the helical flow, these terms can of course only be seen relatively.

Use is particularly considered where weight issues are very critical, but simultaneous sound insulation is essential. In addition to airplanes, this is also the case for other motor-driven or -operated objects, for example mopeds, motorcycles, lawnmowers or even motor saws.

The small dimensions of mufflers according to the invention are also advantageous.

In addition, the helical internals create a more uniform flow, especially in comparison to chamber systems, which leads to a reduction in flow resistance and thus to lower losses.

In order to further reduce the flow resistances, no damping material or sound-absorbing material, as is provided in the prior art, is arranged in the outer ring channel. The gas escaping into the outer channel is braked when it hits sound-absorbing material, which means that the motor has to work against this resistance. This in turn leads to an increase in noise or noise, which, however, is not desirable. According to the invention, the outer ring channel is therefore filled with a gas, particularly preferably with air. The combustion gas emerging from the channel can therefore enter the outer ring channel unhindered, as a result of which the sound waves can also be conducted away unhindered. This leads to the desired sound attenuation.

The advantages achievable by flow diversions do not have to be given up by providing the helical internals. Another advantage is that the helical internals can be provided in a variety of different shapes. Depending on the pitch of the helical screw, an optimal back pressure can be generated for a specific air flow.

It is preferred if the ratio of pitch to diameter of the helical screw is less than 20 and greater than 1, it is particularly preferred if the ratio is 6. The pitch is the length of the screw for one period, measured on the axis. Such conditions can still be achieved by bending a surface area and at the same time are highly effective as damping.

A very low back pressure can also be set by a specific choice of the use of the helical surfaces.

It is preferred if the pitch of the helical screw is constant. When manufacturing the screw surface or the helical internals, it can be tolerated that the material used, for example the sheet metal, warps somewhat. The constant pitch would fluctuate around an average or remain essentially constant.

Alternatively, there is the possibility of a variable pitch for certain applications.

An exemplary embodiment of the invention is described in detail below with reference to the drawing. Show it:

Fig. 1 is a perspective, partially sectioned illustration of an embodiment of the invention; and

2 shows a schematic sectional illustration through a silencer from FIG. 1.

Fig. 1 shows the essential components of the silencer according to the invention. An internal combustion engine (not shown, for example a 2-cylinder aircraft engine) with two cylinders discharges its exhaust gases via two ports 1 and 2, from right to left in the illustration. Exhaust manifolds 3 and 4 begin at connections 1 and 2. These feed the exhaust gas to the actual silencer 7 via compensators 5 and 6. The muffler 7 has an outer casing 10. The casing 10 is fastened to the fuselage (not shown) in this example by means of a schematically indicated fastening 11.

The outer jacket 10 forms an outer annular channel 12. This can have a circular cross section, but is oval in the exemplary embodiment shown. Two inner tubes 20 and 21, each with a circular cross section, pass through the annular channel 12. In these inner tubes 20 and 21, the exhaust manifolds 3 and 4 lead the exhaust gas.

The inner tubes 20 and 21 each surround an inner channel 22 and 23, respectively. This should be given special consideration in the following with regard to the invention.

As can also be seen from the sectional illustration in FIG. 2, helical internals 30 are provided in the two inner channels 22 and 23. The helical internals 30 consist of one of the external requirements of the exhaust gas resistant material, in particular a corresponding metal. The helical internals 30 form a helical screw with a ratio of pitch to diameter of less than 20 and more than 1, in particular 6. They are obtained by bending a metallic surface piece.

The inner tubes 20 and 21 themselves can be made of a similar material and have perforations (not shown). The inner channels 22 and 23 are connected to the outer ring channel 12 through these perforations. The outer ring channel 12 is filled with a gas, in particular with air.

The exhaust gas flow in the muffler 7 is damped by the helical internals 30. As can also be seen in the drawing, each of the helical internals 30 is used from both sides at the same time as a boundary wall of the flow, unlike with separate chambers and constrictions or also with baffle-like internals. Not only the internals, but also the flow is helical. Since the flow resistance to the exit from the perforations into the outer ring channel is low, depending on their dimensions and in comparison, low sound insulation can be achieved.

After passing through the inner channels 22 and 23, the exhaust gases leave the silencer 7 again and emerge from tail pipes 40 and 41, respectively.

Reference list

Connection to cylinder 1 of the internal combustion engine

Connection to cylinder 2 of the internal combustion engine

Exhaust manifold

Compensator

Silencer

coat

Fastening the outer ring channel

inner tube inner tube inner channel in 20 inner channel in 21

helical internals

Tail pipe

Claims

Expectations

1. Muffler for internal combustion engines with a channel (22, 23) through which the exhaust gases are guided, characterized in that helical internals (30) are provided in the channel (22, 23), and that the channel from an outer ring channel ( 12) is surrounded, the outer ring channel (12) being filled with a gas.

2. Silencer according to claim 1, characterized in that the outer ring channel (12) is filled with air.

3. Muffler according to claim 2, characterized in that the inner channel (22, 23) forming inner tube (20, 21) is provided with perforations and thereby the inner channel (22, 23) is connected to the outer ring channel (12) .

4. Silencer according to one of the preceding claims, characterized in that the surface of the helical internals (30) and / or the inside of the inner tube (20, 21) and / or the outside of the inner tube (20, 21) and / or the inside of the outer casing (10) is designed to be sound-soft, that is to say slightly sound-reflecting.

5. Silencer according to one of the preceding claims, characterized in that a plurality of inner tubes (20, 21) are provided, each forming an inner channel (22, 23), and which are surrounded by a common outer annular channel (12).

6. Silencer according to one of the preceding claims, characterized in that the pitch of the helical screw is constant.

7. Silencer according to claim 7, characterized in that the ratio of pitch to diameter of the helical screw is less than 20 and greater than 1.

8. Silencer according to claim 7, characterized in that the ratio of pitch to diameter of the helical screw is 6.