DE102006021737B4 - Filter element for a soot particle filter of an internal combustion engine - Google Patents

Abstract

Filter element (18), in particular for filtering exhaust gases of a diesel internal combustion engine, with an inlet surface (22) and with an outlet surface (24), with a plurality of inlet channels (28), and with a plurality of outlet channels (30), wherein the inlet channels ( 28) and the outlet channels (30) are separated by filter walls (31) from an open-pore material, wherein the inlet channels (28) in cross section in the form of a cross with four legs (34.1, 34.2, 34.3, 34.4), wherein the legs ( 34.1, 34.2, 34.3, 34.4) have a length (L ₁ , L ₂ ) and a width (B ₁ , B ₂ ), and wherein in each case two legs (34.1, 34.4 and 34.2, 34.3) of two adjacently arranged inlet channels (28.1 , 28.2) define a first outlet channel (30.1), characterized in that the end faces (36) of the legs (34.2, 34.2, 34.3, 34.4) of four adjacently arranged inlet channels (28.1, 28.2, 28.3, 28.4) have a second outlet channel (30.2 ) understand coins.

Description

The invention relates to a filter element, in particular for an exhaust system of an internal combustion engine, according to the preamble of claim 1.

From the post-published DE 10 2004 026 060 A1 a filter element is known having an entrance surface and with an exit surface, with a plurality of inlet channels and with a plurality of outlet channels, wherein the inlet channels have a hexagonal cross-section and the outlet channels have a square or diamond-shaped cross section, and wherein the inlet channels and the outlet channels through a filter wall are separated from an open-pored material.

In this case, the exhaust gas to be cleaned flows through the filter walls between the inlet channels and the outlet channels. In the known filter element, soot particles are deposited on the upstream surface of the filter wall over time. These soot particles lead to a reduction in the permeability of the filter wall and, as a result, to an increase in the pressure drop which occurs when the gas flow passes through the filter wall. Accordingly, the so-called "exhaust backpressure" increases. If this exceeds a certain value, the filter is regenerated by burning the separated soot particles. For this purpose, the temperature of the exhaust gas, which is passed through the filter element, increased, which in turn is caused by the injection of additional fuel.

From the US 2006/0 093 784 A1 Filter elements are known with cross-shaped channels. From the EP 1 538 133 A1 is a honeycomb structure is known, which has channels with different cross-section. From the US 4 416 676 A Honeycomb filters are known with Auslasskanalgeometrien, which form flexible connections between the channel walls of the filter.

The object of the present invention is to further improve the operating behavior and the service life of the filter element and to reduce the additional fuel requirement for the regeneration of the filter device.

Disclosure of the invention

This object is achieved with a filter element, in particular for filtering exhaust gases of a diesel engine, with an inlet surface and with an outlet surface, with a plurality of inlet channels and with a plurality of outlet channels, the inlet channels and the outlet channels separated by filter walls of an open-pore material are achieved in that the inlet channels in cross-section in the form of a cross with four legs, that the legs have a length and a width, that each two legs of two adjacent inlet channels define a first outlet channel and that the end faces of the legs of four adjacent arranged inlet channels define a second outlet channel.

The inventive geometry of the cross sections of inlet channels and outlet channels has the advantage that all inlet channels are surrounded exclusively by outlet channels, so that the entire surface of the inner walls of the inlet channels is available as an active filter surface.

Furthermore, the geometry according to the invention also makes it possible to optimally adapt the flow cross section of both the inlet channels and the outlet channels to the volume flow of the exhaust gas to be cleaned. It is also possible to control the proportion of the filter walls in the total volume of the filter element within wide limits. This proportion of the filter walls on the total volume of the filter element has a significant influence on the specific heat capacity of the filter element and can therefore be used to reduce local overheating or temperature loads.

The inventive geometry of the cross sections of inlet channels and outlet channels makes it possible to vary within wide limits the ratio of the cross-sectional areas of the one inlet channel to the two outlet channels. The same applies to the ratio of the surfaces of the filter walls that define the inlet channel and the surfaces of the filter walls that define the outlet channels.

The conditions mentioned are important parameters with the aid of which the number of required regenerations of the filter element can be controlled. Furthermore, the geometry according to the invention of the cross sections of inlet channels and outlet channels leads to a filter element, which are relatively insensitive to thermal stresses resulting from locally different temperature loads.

In advantageous embodiments of the inventions it is provided that the first outlet channels in cross section have the shape of a parallelogram, and that the edge lengths of the parallelogram correspond substantially to the lengths of the legs of the inlet channels. Furthermore, it is provided in an advantageous embodiment of the invention that the second exit channels also have the shape of a parallelogram in cross section, and that the edge lengths of Parallelogram substantially corresponds to the widths of the legs of the inlet channels.

By means of these embodiments of the filter element according to the invention, it is possible to constructively influence both the cross-sectional area of the first outlet channels and the cross-sectional areas of the second outlet channels. Likewise, by the choice of the geometry of the outlet channels determining parameters, namely the length of the legs and the width of the legs, in a simple manner, the hydraulic diameter or the active surface in the outlet channels are varied relative to the corresponding parameters of the inlet channels.

A particularly advantageous variant of the invention provides that the legs of the inlet channels are arranged orthogonal to each other and that the first and second outlet channels in cross section have the shape of a rectangle or a square.

Alternatively, it is also possible for the legs of two adjacent inlet channels to enclose an angle between 100 ° and 170 ° or between 10 ° and 80 °, and that the first and second outlet channels have the shape of a rhomboid or a rhombus in cross section.

Furthermore, the design according to the invention of the cross sections of inlet channels and outlet channels is easy to control in terms of manufacturing technology, which is of great economic importance in particular in the cost-effective production of filter devices having a multiplicity of small inlet channels and even smaller outlet channels.

It has also proved to be advantageous if at least the upstream surface of the filter walls has a catalytic coating. Due to the large surface area, the catalytic effect is enhanced, for example during regeneration of the filter element.

It is particularly advantageous if at least the upstream surface of the filter wall has a catalytic coating. Due to the large surface, the catalytic effect is enhanced, for example, in a regeneration of the filter device.

The filter elements according to the invention can advantageously be produced by extruding a ceramic material, preferably cordierite or silicon carbide, or sintered metal.

Alternatively, it is also possible to produce the filter element from a plurality of stacked layers of preformed flat materials.

Further advantages and advantageous embodiments of the invention are the following drawings, the description and the claims removable. All features described in the drawing, the description and the claims may be essential to the invention both individually and in any combination.

drawings

Show it:

1 a schematic representation of an internal combustion engine with an exhaust gas aftertreatment device according to the invention;

2 a filter element according to the invention in longitudinal section and

3 and 4 Cross sections of inventive inlet channels and

5 a partial section through an embodiment of a filter element according to the invention.

Description of the embodiments

In 1 an internal combustion engine carries the reference number 10 , The exhaust gases are via an exhaust pipe 12 derived in which a filter device 14 is arranged. With this soot particles from the exhaust pipe 12 filtered exhaust gas filtered out. This is particularly necessary in diesel internal combustion engines to comply with legal requirements.

The filter device 14 includes a cylindrical housing 16 in which a rotationally symmetrical in the present embodiment, a total also cylindrical filter element 18 is arranged.

In 2 is a cross section through a filter element according to the invention 18 shown. The filter element 18 For example, may be prepared as an extruded molded article of a ceramic material, such as cordierite.

The filter element 18 will be in the direction of the arrows 20 flows through not shown exhaust gas. An entrance area has in 2 the reference number 22 while an exit surface in 2 the reference number 24 Has.

Parallel to a longitudinal axis 26 of the filter element 18 run several inlet channels 28 in alternation with outlet channels 30 , The entrance channels 28 are at the exit surface 24 locked. The sealing plugs are in 2 shown without reference number. In contrast, the exit channels 30 at the exit surface 24 open and in the area of the entrance area 22 locked.

The flow path of the unpurified exhaust gas thus leads into one of the inlet channels 28 and from there through a filter wall 31 in one of the exit channels 30 , This is exemplified by arrows 32 shown.

In 3 is a first embodiment of an entrance channel according to the invention 28 shown in cross section. This entrance channel 28 has in cross section the shape of a cross, consisting of four legs 34.1 to 34.4 , The thigh 34.1 to 34.4 each of filter walls 31 , which have not all been provided with reference numerals for reasons of clarity, limited. At the end of each thigh 34 is an end face 36 present, which also as a filter wall 31 is trained.

In 3 are the most important geometric variables, namely the length L _{1 of} the legs 34 and their widths B ₁ drawn. In the embodiment according to 3 have all thighs 34 the same length L ₁ and the same width B ₁ on.

In the embodiment of an entrance channel 28 according to 4 has the thigh 34.1 a greater length than the other legs 34.2 to 34.4 ,

Furthermore, the thighs have 34.1 and 34.3 a width B ₁ , while the legs 34.2 and 34.4 a reduced width B ₂ relative to the width B ₁ . By comparing the two embodiments according to 3 and 4 it becomes clear that with respect to the geometric parameters length and width of the legs 34 many variations of the cross-shaped cross-section of the inlet channels 28 are possible, the design and optimization of a filter element according to the invention 18 can be used.

In 5 is a partial section through a filter element according to the invention 18 shown. It becomes clear that the filter element 18 by juxtaposing several inlet channels 28 with the associated filter walls 31 is formed. Exemplary is a first entrance channel 28.1 with a reference numeral in 5 Mistake. Right above the entrance channel 28.1 is a second entrance channel 28.2 intended. The thigh 34.1 and 34.4 of the entrance channel 28.1 as well as the thighs 34.2 and 34.3 of the entrance channel 28.2 surround a first exit channel 30.1 ,

Because at the entrance channels 28.1 and 28.2 the lengths L _{1 of} the legs 34 are the same, has the first exit channel 30.1 a square cross section.

The front of each leg 34 the entrance channels 28.1 . 28.2 . 28.3 and 28.4 limit a second exit channel 30.2 , At the in 5 illustrated embodiment also have the second outlet channels 30.2 a square cross section, wherein the edge length of the width B _{1 of} the legs 34 equivalent.

For clarity, in 5 not all thighs 34 and all channels 28 and 30 provided with reference numerals. By adding further entrance channels 28 in the manner described above, a filter element according to the invention 18 be formed with arbitrarily large cross-section.

The entrance channel 28.4 points opposite the entrance channels 28.1 to 28.3 the peculiarity of being that thigh 34.2 is longer than the other thighs 34.1 . 34.3 and 34.4 (without reference number). In the adjacent thereto arranged inlet channel 28.5 is accordingly the length L of the thigh 34.4 extended. As a result, that of the entrance channels 28.4 and 28.5 enclosed first entrance channel 30.1 a rectangular cross-section.

This example clearly shows that by changing the width and / or length of the legs 34 the ratio of the cross-sectional areas of the inlet channels 28 to the cross-sectional areas of the first exit channels 30.1 and the second exit channels 30.2 can be varied within wide limits of the requirements of the application. Also, the proportion of filter walls 31 (without reference in 5 ) based on the total volume of the filter element 18 be varied. This allows the heat capacity of the filter element 18 be adapted to the requirements of the application in a simple manner.

Claims (10)

Filter element ( 18 ), in particular for filtering exhaust gases of a diesel internal combustion engine, having an entry surface ( 22 ) and with an exit surface ( 24 ), with a plurality of entry channels ( 28 ), and with a plurality of exit channels ( 30 ), whereby the entry channels ( 28 ) and the exit channels ( 30 ) through filter walls ( 31 ) are separated from an open-pore material, wherein the inlet channels ( 28 ) in cross-section the shape of a cross with four legs ( 34.1 . 34.2 . 34.3 . 34.4 ), wherein the legs ( 34.1 . 34.2 . 34.3 . 34.4 ) have a length (L ₁ , L ₂ ) and a width (B ₁ , B ₂ ), and wherein two legs each ( 34.1 . 34.4 and 34.2 . 34.3 ) of two adjacently arranged inlet channels ( 28.1 . 28.2 ) a first exit channel ( 30.1 ), characterized in that the end faces ( 36 ) of the thighs ( 34.2 . 34.2 . 34.3 . 34.4 ) of four adjacent inlet channels ( 28.1 . 28.2 . 28.3 . 28.4 ) a second exit channel ( 30.2 ) limit. Filter element ( 18 ) according to claim 1, characterized in that the first outlet channels ( 30.1 ) in cross section have the shape of a parallelogram, and that the edge lengths of the parallelogram substantially the lengths (L ₁ , L ₂ ) of the legs ( 34 ) of the entry channels ( 28 ) corresponds. Filter element ( 18 ) according to claim 1 or 2, characterized in that the second exit channels ( 30.2 ) have in cross-section the shape of a parallelogram, and that the edge lengths of the parallelogram substantially the widths (B ₁ , B ₂ ) of the legs ( 34 ) of the entry channels ( 28 ) corresponds. Filter element ( 18 ) according to any one of the preceding claims, characterized in that the legs ( 34.1 . 34.2 . 34.3 . 34.4 ) of the entry channels ( 28 ) orthogonal to each other, and that the first and second exit channels ( 30.1 . 30.2 ) in cross section have the shape of a rectangle or a square. Filter element ( 18 ) according to one of claims 1 to 3, characterized in that the limbs ( 34 ) of two adjacent entry channels ( 28 ) include an angle between 100 ° and 170 ° or between 10 ° and 80 °, and that the first and second exit channels ( 30.1 . 30.2 ) in cross section have the shape of a rhomboid or a rhombus. Filter element ( 18 ) according to one of the preceding claims, characterized in that at least the upstream surface of the filter walls ( 31 ) has a catalytic coating. Filter element ( 18 ) according to one of the preceding claims, characterized in that the filter element ( 18 ) is produced by extrusion. Filter element ( 18 ) according to one of the preceding claims, characterized in that the filter element ( 18 ) is made of a ceramic or a glass-ceramic material, in particular of cordierite or of silicon carbide. Filter element ( 18 ) according to one of claims 1 to 7, characterized in that the filter element ( 18 ) is made of sintered metal. Filter element according to one of the preceding claims, characterized in that the inlet channels ( 28 ) at the entrance surface ( 22 ) and at the exit surface ( 24 ) are closed, and that the outlet channels ( 30 ) at the entrance surface ( 22 ) are closed and at the exit surface ( 24 ) end up.

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