DE102007051534A1 - Sound absorber for exhaust gas system of internal combustion engine, has sound absorbing component and cleaning component, which are formed from porous metal substrate, where components are connected together as single piece - Google Patents

Abstract

The absorber (10) has a sound absorbing component (12) and a cleaning component (18), which are formed from a porous metal substrate. The components are connected together as a single piece, and the sound absorbing component comprises a hollow ball structure. The cleaning component comprises a floating structure, and is formed as a particle filter and/or as a catalytic treatment device. The components are manufactured in a same production step, and a carrier matrix at a region of the components comprises the ball structure. An exhaust gas treatment device is provided in the absorber. An independent claim is also included for a method for manufacturing a sound absorber.

Description

The The invention relates to a silencer, in particular for an exhaust system of an internal combustion engine.

It is known to produce such mufflers with sound-absorbing materials. So z. B. already in the DE 199 49 271 B4 proposed to use a metallic hollow ball substrate for sound absorption. Such hollow spherical substrates have good sound absorption properties due to the high volume of trapped air.

porous Metal substrates have also been used for exhaust treatment devices such as particle filters or catalytic exhaust gas purification discussed.

The Invention builds on these developments to create a silencer to improve.

According to the invention a muffler, in particular for an exhaust system an internal combustion engine, an integrated exhaust treatment device on, wherein both at least one sound-absorbing component and at least one cleaning component made of a porous Metal substrate are formed. Have porous metal substrates Features on, both for soundproofing as well are positive for exhaust treatment. You are at one very large surface and a very big one Volume included lightly and yet reasonably well inexpensive to produce. By integration of an exhaust treatment device in the muffler can be a space saving reach while at the same time the pollutant content of the exhaust gas effectively reduced.

In A preferred embodiment of the invention is sound-damping Component and cleaning component integrally connected. In principle, the silencer, maybe apart from a separate outer housing, including the integrated Exhaust treatment device consist of a single component, that from the external sound-absorbing component and disposed within the sound attenuating member Cleaning component is formed, both of porous metal substrate, possibly with different structures.

Preferably the sound-damping component has a hollow sphere structure on, advantageously with substantially closed cells, so that predominantly a sound-absorbing effect is achieved.

The Cleaning component, however, preferably has a sponge structure on, so an open-cell structure, which it through the muffler flowing exhaust gas without significant pressure losses allowed to pass the cleaning component. The cleaning component can, for example as a particle filter and / or as a catalytic treatment device be educated. Here offers a known hollow body structure at, in which the walls of the hollow body arranged so are that flowing through the muffler Exhaust gas in any case at least one wall of the cleaning component must happen.

Of the Muffler according to the invention records characterized by the fact that the sound-absorbing component and the cleaning component to be manufactured in the same step can. In this way, despite the expensive starting material keep the production costs under control.

One preferred manufacturing method provides that a carrier matrix is provided, which has a first portion of the corresponds to later sound-absorbing component, and a second section, the later cleaning component equivalent. The two sections of the carrier matrix will be covered with a mixture containing a metal powder and contains a binder. The result of the last step Component, ie the coated carrier matrix, becomes one Sintered process subjected to the carrier matrix gets destroyed. The carrier matrix can, for. B. off a polyurethane foam or other suitable polymeric foam consist. On this carrier matrix is a preferably liquid mixture with a metal powder and a binder applied, wherein the metal powder z. B. FeCrAl contain or can consist of it. During sintering, the metal powder particles combine while due to the high temperatures, the carrier matrix decomposed pyrolytically. This method of producing porous Metal substrates are known and used to produce a variety of Substrate structures applied.

Especially is it possible to make a carrier matrix in a section a first structural form, for. B. a closed-cell Hollow sphere structure, and in another section a different structural form, z. B. an open-cell foam structure having. The structure of Carrier matrix is found after the sintering process in finished component again. That way quickly and easily a one-piece component in one Work step, which is both different sound-absorbing as well as different gas-permeable properties in different sections. This technique is suitable for this very good for making a silencer with a integrated exhaust treatment device.

Preferably, the carrier matrix in Be rich of the later sound-absorbing component on a spherical structure, while having a sponge structure in the region of the later cleaning component.

Around also be used for a catalytic exhaust treatment to be able to at least the cleaning component after the Sintering process with a catalytic coating be provided. This can be in the form of a commercial washcoat and a solution with catalytically active substances the porous metal substrate are applied.

Further Features and advantages of the invention will become apparent from the following in conjunction with the single figure described embodiment. The single FIGURE shows a schematic sectional view of an inventive Silencer.

The silencer 10 has a sound-absorbing component 12 , which is formed in the form of a shell which has a chamber-shaped cavity 13 encloses. The silencer 10 is so integrated into an exhaust system of an internal combustion engine, that an exhaust gas flow G into the cavity 13 through an inlet 14 enters and through an outlet 16 exits again. Inlet 14 and outlet 16 Make the only gas permeable passage through the cavity 13 and the muffler 10 represents.

The sound-absorbing component 12 consists here of a layer of a porous metal substrate in the form of a hollow sphere structure, as is known in the art. This is a substantially closed-cell foam, with a pore size of about 0.1 to 5 mm. The layer thickness is preferably between 5 and 20 mm.

The sound-absorbing component 12 may be enclosed by a solid, rigid and gas-impermeable outer shell, which may also be used for coupling to the remainder of the exhaust system, or, as shown, it may also be the sound-absorbing component 12 the gas-impermeable outer shell of the silencer 10 form.

Inside the cavity 13 is a cleaning component 18 arranged, which is also formed of a porous metal substrate.

In contrast to the sound-absorbing component 12 has the cleaning component 18 However, a sponge structure, so a more open-cell structure, which allows a gas flow with low pressure drop.

The cleaning component 18 is here in the form of two inverted nested hollow cones or hollow truncated cones, which are arranged so that the exhaust gas as it flows through the muffler 10 at an obtuse angle to at least one wall of the cleaning component 18 butt and this has to happen, from the inlet 14 to the outlet 16 to get. The gas flow G is illustrated in the figure by the arrows. Of course, any other suitable geometry for the cleaning component 18 can be used, for. For example, this could be the cavity 13 completely complete.

The cleaning component 18 and possibly also the inside of the sound-absorbing component 12 are coated with a catalytically active substance, the z. B. can cause a decomposition of nitrogen oxides.

The sound-absorbing component 12 due to its hollow sphere structure has a lower gas permeability than the cleaning component 18 , so that at a gas flow significantly higher pressure loss occurs than in the sponge structure of the cleaning component 18 , In the inner edge regions of the sound-absorbing component 12 therefore penetrates only a small amount of gas. Essentially, however, the sound attenuation takes place by sound absorption in the sound-absorbing component 12 , while the exhaust treatment substantially in the cleaning component 18 takes place.

The silencer 10 is prepared by first preparing a support matrix of a PU foam or PU spheres or a foam or spheres of another suitable polymer.

The carrier matrix already has a microstructure that corresponds to the microstructure of the later sound-damping or cleaning components 12 . 18 equivalent.

The carrier matrix has a first section, the later sound-absorbing component 12 corresponds, and having a hollow sphere structure. Pore size and wall thickness of this section already correspond to those of the later sound-absorbing component 12 ,

The carrier matrix also has a second section, which is the later cleaning component 18 equivalent. In this, the carrier matrix has a sponge structure, that of the sponge structure of the later cleaning component 18 equivalent. Again, the geometric dimension, shape and wall thickness are substantially identical to those of the later cleaning component 18 ,

The both sections of the carrier matrix are prepared separately and then assembled.

After this the individual parts of the carrier matrix were produced, They are individually with a preferably liquid mixture coated with a binder and a metal powder, for. FeCrAl, contains. This can be z. B. by dipping, spraying or any other suitable technique. In this process step covers the mixture the surfaces of the microstructure and the Carrier matrix, so that this substantially completely to be covered by the mixture. Subsequently, the composed of individual sections of the coated carrier matrix.

The but both sections of the support matrix could also manufactured in one piece in a suitable foam process or already assembled before coating.

In a next process step is the coated Carrier matrix a sintering process at high temperatures in which the metal powder particles become one-piece, connect continuous structure, while the carrier matrix itself and the binder pyrolytic due to the high temperatures decompose. What remains is therefore an image of the microstructure the carrier matrix in the form of a skeleton of the sintered metal powder particles.

In the finished silencer 10 are the sound-absorbing component 12 and the cleaning component 18 integral with each other, but have different microstructures.

The cleaning component 18 is preferably still provided with a catalytically active coating in the form of a so-called washcoat, are applied to the catalytically active substances for exhaust gas treatment, as is known from conventional methods. This may also be the inner wall of the sound-absorbing component 12 be coated. The choice of microstructure and the use of the coating is carried out, of course, so that no bypass for unpurified exhaust gas through the sound-absorbing component 12 persists.

The thus obtained silencer 10 Can still be used in a solid metal housing to make it less sensitive to mechanical damage (not shown). But it can also be used in the state shown, in which case, of course, the outer layer of the sound-absorbing component 12 is designed gas impermeable.

By the invention can be easily multifunctional silencer with an integrated Produce exhaust treatment device. Wall thicknesses, pore sizes and let geometric dimensions of the muffler Just change, because for these only appropriate changes must be made in the carrier matrix. Thus, the invention also proves to be very adaptable.

Alternatively, it would also be possible for the cleaning component 18 made of a wire mesh or metal fibers and the prefabricated cleaning component 18 in the also separately prefabricated sound-absorbing component 12 insert and fix there.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• - DE 19949271 B4 [0002]

Claims (11)

Silencer, in particular for an exhaust system of an internal combustion engine, having an integrated exhaust gas treatment device, wherein at least one sound-damping component ( 12 ) and at least one cleaning component ( 18 ) are formed of a porous metal substrate. Silencer according to Claim 1, characterized in that the sound-damping component ( 12 ) and cleaning component ( 18 ) are integrally connected. Silencer according to one of the preceding claims, characterized in that the sound-damping component ( 12 ) has a hollow sphere structure. Silencer according to one of the preceding claims, characterized in that the cleaning component ( 18 ) has a sponge structure. Silencer according to one of the preceding claims, characterized in that the cleaning component ( 18 ) is designed as a particle filter and / or as a catalytic treatment device. Method for producing a silencer according to one of the preceding claims, characterized in that the sound-damping component ( 12 ) and cleaning component ( 18 ) are manufactured in the same step. Method according to claim 6, comprising the following steps: a carrier matrix is provided which has a first section which is connected to the later sound-damping component ( 12 ), and a second section, the later cleaning component ( 18 ), - the two sections of the support matrix are coated with a mixture containing a metal powder and a binder, - the coated support matrix is subjected to a sintering process in which the support matrix is destroyed. Method according to claim 7, characterized in that the carrier matrix in the region of the later sound-damping component ( 12 ) has a ball structure. Method according to one of claims 7 and 8, characterized in that the carrier matrix in the region of the later cleaning component ( 18 ) has a sponge structure. Method according to one of claims 7 to 9, characterized in that the portion which the subsequent sound-damping component ( 12 ), and the section corresponding to the later cleaning component ( 18 ), prepared separately and coated and then assembled to the carrier matrix. Method according to one of claims 6 to 10, characterized in that at least the cleaning component ( 18 ) is provided after the sintering process with a catalytically active coating.