WO2012045673A1 - Exhaust-gas recirculation filter, internal combustion engine - Google Patents

Abstract

The present invention relates to an internal combustion engine (1), in particular of a motor vehicle, having at least one fresh air line (6) for supplying fresh air to cylinders (4) of the internal combustion engine (1), having at least one exhaust line (11) for discharging exhaust gas from the cylinders (4), having at least one exhaust-gas recirculation line (16) which fluidically connects the exhaust line (11) to the fresh air line (6), having an exhaust-gas recirculation cooler (19) which is arranged in the exhaust-gas recirculation line (16), and having a filter element (29) which is arranged in the exhaust-gas recirculation line (16) and which serves for filtering out particles entrained in the recirculated exhaust gas. The efficiency of the exhaust-gas recirculation can be improved if the filter element (29) in the exhaust-gas recirculation line (16) is arranged downstream of the exhaust-gas recirculation cooler (19).

Description

 Exhaust gas recirculation filter, internal combustion engine

The present invention relates to an exhaust gas recirculation filter for installation in an external exhaust gas recirculation line of an internal combustion engine, in particular of a motor vehicle, having the features of the preamble of claim 1 and an internal combustion engine equipped therewith.

An internal combustion engine, which is used in particular in a motor vehicle, usually has a fresh air line for supplying fresh air to cylinders of the internal combustion engine and an exhaust pipe for discharging exhaust gas from the cylinders. In addition, in a modern

Internal combustion engine for reducing pollutant emissions

Exhaust gas recirculation line may be provided which the exhaust pipe with the

Fresh air line fluidly connects and thus returns exhaust gas from the exhaust pipe to the fresh air line. In order to improve the charging of the internal combustion engine, it is customary to provide an exhaust gas recirculation cooler in the exhaust gas recirculation line in order to cool the recirculated exhaust gas. If such

Exhaust gas recirculation line runs outside the internal combustion engine, it is an external exhaust gas recirculation line. In an external exhaust gas recirculation, it may be appropriate to connect the exhaust gas recirculation line downstream of a catalyst and / or a particulate filter to the exhaust pipe to

be able to recycle post-treated or purified exhaust gases. The problem here is that conventional catalysts and particulate filter have ceramic substrates and secrete due to aging effects particles that are carried in the exhaust gas flow. For example, the vibrations and vibrations occurring during operation of an internal combustion engine produce a certain amount of abrasion on a ceramic catalyst element. This abrasion forms particles that can be carried along by the exhaust gas flow. Furthermore Metallic particles, such as welding beads, can occur which, for example, can be detached from the welded assembly exhaust pipe by vibration. Such particles can damage the internal combustion engine as well as a charge device optionally arranged in the fresh air line.

From DE 10 2008 038 235 A1 an exhaust gas recirculation filter is known, which can be installed in such an external exhaust gas recirculation line. Such an exhaust gas recirculation filter has a filter housing in which a filter element is arranged, which filters out particles which are entrained in the recirculated exhaust gas. This effectively prevents damage to the

Avoid internal combustion engine due to such particles. The known exhaust gas recirculation filter is provided for installation upstream of the exhaust gas recirculation cooler in the exhaust gas recirculation line in order to protect the exhaust gas recirculation cooler from exposure to particles.

It has been found that such an exhaust gas recirculation filter has a comparatively high flow resistance, which makes exhaust gas recirculation more difficult. In particular, this makes a so-called low-pressure exhaust gas recirculation difficult, in which the exhaust gas recirculation line downstream of a turbine of an exhaust gas turbocharger exhaust gas to the exhaust line

is connected and fresh air side upstream of a compressor of the

Exhaust gas turbocharger is connected to the fresh air line.

The present invention deals with the problem for a

Internal combustion engine or for an exhaust gas recirculation filter of the aforementioned type to provide an improved embodiment, which is characterized in particular by an efficient exhaust gas recirculation. Furthermore, in particular a

Low pressure exhaust gas recirculation can be realized. In addition, optionally the protection against particles entrained in the exhaust gas should be improved. This problem is inventively by the objects of

solved independent claims. Advantageous embodiments are

Subject of the dependent claims.

The invention is initially based on the general idea, the filter element or the exhaust gas recirculation filter in the return line downstream of the

To arrange exhaust gas recirculation cooler. This measure is based on the knowledge that the flow resistance of the filter element is a significant

Has dependence on the temperature of the filtered exhaust gas. The

Temperature dependence of the flow resistance is so strong that by the arrangement of the filter element or the exhaust gas recirculation filter downstream of the exhaust gas recirculation cooler, the flow resistance, for example. By a factor of 10 can be reduced compared to an arrangement thereof

Filter element or the same exhaust gas recirculation filter upstream of the

Exhaust gas recirculation cooler. In addition, the proposed arrangement further advantages. Due to the proposed positioning of the

Filter element or the exhaust gas recirculation filter on the cold side of

Exhaust gas recirculation cooler can be used cheaper materials for the production of the exhaust gas recirculation filter or the filter element. For example, a filter housing of the exhaust gas recirculation filter, in which the filter element is arranged, are now made of plastic, while in a conventional arrangement on the hot side of the exhaust gas recirculation cooler must necessarily be made of metal or ceramic.

According to a particularly advantageous embodiment, a mist eliminator may be provided downstream of the exhaust gas recirculation filter or the filter element. With the help of such a droplet can liquid droplet, in particular water droplets, which are carried in the exhaust gas flow, from the exhaust gas flow are excreted. Such drops of liquid can arise in and downstream of the exhaust gas recirculation cooler, especially by condensation. In particular, the drops are predominantly formed on the cold walls of the radiator. For example, on the filter element a

Precipitate condensing liquid form, the progressive

Condensation leads to a release of droplets to the exhaust gas flow.

Such droplets can represent a comparatively high mechanical load for a compressor of an exhaust gas turbocharger, which can lead to abrasion and corrosion of a compressor wheel or a compressor housing. The arrangement of the mist eliminator downstream of the filter element can reduce such a risk of damaging the compressor.

According to a particularly advantageous embodiment of the

Droplet separator in a filter housing, in which also the filter element

is arranged to be integrated. As a result, a compact design for an exhaust gas recirculation filter is created, which in its filter housing downstream of the

Filter element containing the mist eliminator. In this way, the exhaust gas recirculation filter with integrated droplet separator can be arranged particularly simply downstream of the exhaust gas recirculation filter in the exhaust gas recirculation line.

In another advantageous embodiment, a sump for collecting separated liquid may also be formed in the filter housing. In this way, the separated liquid for operating phases of the internal combustion engine in which condensate is obtained in the recirculated exhaust gas, be collected or stored to later in operating phases in which no condensation, but rather an evaporation or a

Evaporation of the liquid takes place, the collected or stored

Evaporate or vaporize the liquid and remove it from the sump to be able to. Thus, the sump forms a within the filter housing

Catcher for condensate.

According to another advantageous embodiment, moreover, a heater for heating the sump or collected in the sump

Be provided liquid. In this case, the separated liquid can also be actively evaporated, for example. To avoid overfilling or overflow of the sump. By virtue of this measure, the sump can be designed comparatively small with regard to its collecting volume. Furthermore, the exhaust gas recirculation filter for the evaporation or evaporation of the liquid collected in the sump is not dependent on an operating phase of the internal combustion engine, which also provides sufficient heat for evaporating the stored in the sump condensate in the exhaust downstream of the exhaust gas recirculation cooler.

In a particularly advantageous embodiment, said heater may comprise at least one PTC element, wherein PTC stands for Positive Temperature Coefficient. As a result, the temperature desired for heating the sump can be set particularly easily, since such a PTC element is known with regard to a predetermined target temperature

is self-regulating.

Suitably, the heater can heat a lying in the installed position of the exhaust gas recirculation filter in the direction of gravity bottom bottom of the sump. This results in a particularly effective heat coupling between heating and condensate.

The heater may also be configured as a separate component, which is installed in a filter housing formed on the heating receptacle. Especially Thus, the heater can be manufactured as a separate unit and installed as such unit in the filter housing.

In order to favor the evaporation or the removal of the condensate from the sump, a wick may be provided, which projects on the one hand into the sump and on the other hand is exposed to a gas flow. In this case, the wick can be laid so that it is exposed to the exhaust gas flow in the exhaust pipe or in the exhaust gas recirculation line or that it is exposed to the fresh air flow in the fresh air line.

Additionally or alternatively, further advantageous embodiments in any combination may have the following features. For example, a drain opening may be provided which is fluidly connected to the sump to the accumulated in the sump liquid from the filter housing

lead out, e.g. directly into an environment of the exhaust system,

optionally in conjunction with a suitable valve device. This drain opening can expediently be arranged in the region of the filter element, in particular radially thereto. Optionally, a dividing wall can be arranged between the drain opening and the filter element, in order to avoid a direct flow of the drain opening and an arrival or flow through the

Favor drip eliminator. Further, a transverse wall, the sump in a fluidically connected to the drain opening drainage chamber and a

Divide the collecting space, wherein the transverse wall is made permeable to the separated liquid, for example by means of at least one

Through opening, which fluidly connects the drainage chamber through the transverse wall with the collecting space. Also, this transverse wall prevents direct flow of the inlet region of the drain opening and thus supports an arrival or flow through the droplet, which improves its efficiency. In another embodiment, the mist eliminator a

Have drainage device which supplies separated liquid to the sump. In this way, the efficiency of the mist eliminator is improved. Likewise, the effect of the swamp is optimized.

Suitably, the sump may be formed by a formed in the interior of the filter housing, in particular trough-shaped depression, which is arranged in the installed position of the exhaust gas recirculation filter in the direction of gravity below the Tropfenabscheiders and open at the top. As a result, the sump has a particularly simple geometric shape, whereby it is also particularly simple and inexpensive to implement within the filter housing.

The filter housing may have, downstream of the drop separator, a guide collar projecting counter to the exhaust gas flow direction, which collects liquid moving along an inner side of the filter housing in the exhaust gas flow direction and discharges in the direction of the sump. Because the

Condensation does not take place exclusively on the filter element, but can also take place on the inside of the filter housing, with the aid of

Guide collar leakage of this condensate are hindered from the filter housing.

The sump can also extend over a substantial portion of the filter element, that is, clearly opposite to the exhaust gas flow direction away from the mist eliminator. As a result, the collecting volume of the sump can be increased accordingly.

In a particularly advantageous embodiment, the mist eliminator can be configured as a lamella separator, which several more parallel to each other has extending and arranged in the flow path of the exhaust gas flow slats. Such fins may have a wave profile, in particular in the exhaust gas flow direction. Optionally, each lamella can have at least one collecting channel oriented in the direction of the gravitational force, which discharges the separated liquid, in particular to a drainage device of the droplet separator.

If a drainage device is provided, the drainage device can supply the separated liquid to the aforementioned sump.

The slats have a slat longitudinal direction, with which they in the

Exhaust flow direction are oriented, and a lamella transverse direction, with which they protrude into the flow path of the exhaust gas. Appropriately it can now be provided that the slats are arranged with their slats transverse direction with respect to the direction of gravity inclined, in particular

It can be provided that the lamellae are inclined with respect to the direction of gravity in such a way that they come from or to the filter element in the

Direction of gravity increasing distance. Additionally or alternatively to the inclination of the Lammellenquerrichtung can be provided that the

Slats with their slats longitudinal direction relative to the

 Exhaust flow direction are inclined. The inclination or adjustment of the slats with respect to the exhaust gas flow direction with respect to their longitudinal or

Transverse direction favors the separation effect, since the employment in the

Longitudinally inevitably to a deflection or deflection of the

Exhaust gas flow leads to the respective lamella, so that entrained

Liquid droplets in any case meet against such a blade and attach to it, while the inclination in the transverse direction causes the exhaust gas flow along the lamella deposited liquid droplets along the slat transverse direction drives and thus supports the discharge of the separated liquid.

Suitably, the slats can extend into the aforementioned sump, resulting in a particularly simple structure. Furthermore, it is possible for the lamellae to be designed as a monolithic lamella block which comprises a lamella carrier connecting the lamellae to one another. As a result, the slats can be particularly simple, namely use as a unit in the form of the fins block in the filter housing. Optionally, the monolithic lamella block may comprise the aforementioned partition wall and / or the likewise aforementioned transverse wall.

Preferably, the filter housing is made of plastic. As a result, the exhaust gas recirculation filter is particularly inexpensive.

The filter element preferably has a filter material of a lattice structure. Preference is given to a woven grid structure. A mesh size of the lattice structure is preferably less than 100 pm, so that solid particles larger than 100 pm can be reliably filtered out of the exhaust gas flow.

According to further advantageous embodiments, which can be combined as desired with the aforementioned embodiments, the following features can be realized in any combination.

For example, the filter housing may have an exhaust gas inlet and axially aligned therewith an exhaust gas outlet. This gives the exhaust gas recirculation filter a comparatively low flow resistance. In this case, the filter element can be arranged coaxially with the exhaust gas inlet and exhaust gas outlet, which likewise favors a low flow resistance. Preferably, the filter housing can be a monolithic inlet block having a Has exhaust inlet, and having a monolithic exhaust block having an exhaust outlet, which simplifies the structure of the filter housing. Optionally, then a monolithic intermediate block may be provided, which is arranged axially between the inlet block and the outlet block. In addition, the intermediate block between the inlet block and the outlet block can be axially braced, whereby the intermediate block by this tension on

Filter housing is attached or integrated therein. Suitably, the above-mentioned drain opening may be formed in the intermediate block.

Independently of this, furthermore, the droplet separator can be arranged in a separation chamber of the filter housing, which merges via a cross-sectional reduction into an exhaust gas outlet. As a result, the flow-through cross-section can be kept substantially constant despite the filter element and droplet separator within the filter housing in order to avoid excessive pressure increase in the flow through the exhaust gas recirculation filter. Appropriately, at least one pressure relief opening can now be provided, which the

Separating chamber through the cross-section reduction fluidly connects with the exhaust gas outlet.

The filter element is expediently configured as a mechanically filtering filter element, that is, by a mesh size or pore size of its

Filter material for the exhaust gas permeable and impermeable to the particles to be deposited. For example, the filter element may comprise a filter material of lattice structure secured to an annular flange by which the filter element is secured to the filter housing, wherein it may be provided in particular that the annular flange axially braces axially between the aforesaid intermediate block and said inlet block and thereby is attached to the filter housing. The engine equipped with such an exhaust gas recirculation filter can preferably be designed as a supercharged internal combustion engine having a charging device in the fresh air line. The exhaust gas recirculation line is then connected upstream of the charging device to the fresh air line.

In particular, in a preferred embodiment, the charging device may be formed by a compressor of an exhaust gas turbocharger whose turbine is arranged in the exhaust pipe, in which case the exhaust gas recirculation line is connected downstream of the turbine to the exhaust pipe. As a result, a low-pressure exhaust gas recirculation is ultimately realized.

As already explained, a droplet separator can be arranged in the exhaust pipe downstream of the filter element, which is preferably arranged in the filter housing, which also contains the filter element.

Particularly useful is an embodiment in which the

Exhaust gas recirculation filter is installed in the exhaust gas recirculation line so that the

Exhaust gas flow direction in the filter housing runs perpendicular to the direction of gravity. This makes it possible to use the gravity for discharging or for driving the deposited condensate, for example. To supply the condensate to the sump.

Other important features and advantages of the invention will become apparent from the dependent claims, from the drawings and from the associated

Description of the figures with reference to the drawings.

It is understood that the features mentioned above and those yet to be explained not only in the combination specified in each case, but also in other combinations or alone, without departing from the scope of the present invention.

Preferred embodiments of the invention are illustrated in the drawings and will be described in more detail in the following description, wherein like reference numerals refer to the same or similar or functionally identical components.

Show, in each case schematically,

Fig. 1 is a greatly simplified schematic diagram of a schematic

 Internal combustion engine,

2 shows an isometric longitudinal section of an exhaust gas recirculation filter,

3 to 5 each show an isometric longitudinal section of the exhaust gas recirculation cooler, but other embodiments.

According to Fig. 1, an internal combustion engine 1, which in a

Motor vehicle may be arranged, an engine block 2, the more

Contains combustion chambers 3. In the example, four combustion chambers 3 are shown without limiting the generality. The combustion chambers 3 are each located in a cylinder 4, in which a piston, not shown, is arranged adjustable in stroke.

In that regard, the internal combustion engine 1 is a piston engine, which may be designed as a diesel engine or as a gasoline engine. Shown is a series engine. Likewise, a V-engine or a W-motor or a boxer engine is conceivable. The internal combustion engine 1 has a fresh air system 5, passes through the fresh air to the combustion chambers 3. The fresh air system 5 has in the example a fresh air line 6, in which an air filter 7 is arranged and to a Fresh air manifold 8 leads, which supplies the fresh air via individual tubes 9 to the individual combustion chambers 3. Basically, the fresh air system 5 can also be designed with two columns, ie have two parallel fresh air lines 6. Furthermore, the internal combustion engine 1 has an exhaust system 10, via which exhaust gas is discharged from the combustion chambers 3. The exhaust system 10 has z. Ex. An exhaust pipe 1 1, which goes off from an exhaust manifold 12, which in turn is connected via individual tubes 13 to the combustion chambers 3. Likewise, it is possible to design the exhaust system 10 in two columns, so that it then has two mutually parallel exhaust pipes 1 1. The exhaust system 10 may include a particulate filter 14 which is disposed in the exhaust pipe 11. In addition, the exhaust system 10 further exhaust purification devices, such. For example, an SCR catalyst, which is usually arranged downstream of the particulate filter 14, and an oxidation catalyst, not shown, which is usually arranged upstream of the particulate filter 14. The particle filter 14 is expediently arranged downstream of a turbine 24 so that the turbine 24 has as much exhaust gas enthalpy as possible. In addition, muffler devices may be present.

The internal combustion engine 1 is also equipped with an exhaust gas recirculation system 15, which is also referred to below as the EGR system 15. It serves to recirculate exhaust gas from the exhaust system 10 to the fresh air system 5. For this purpose, the EGR system 15 an exhaust gas recirculation line 16, which in the

Also referred to as EGR line 16 below. The EGR line 16 is connected via an extraction point 17 to the exhaust system 10 and to the exhaust pipe 1 1 and connected via a discharge point 18 to the fresh air system 5 and at the fresh air line 6. The removal point 17 is positioned downstream of the particle filter 14. The discharge point 18 is positioned downstream of the air filter 7. The EGR system 15 contains in the EGR line 16 an exhaust gas recirculation cooler 19, which is also referred to below as an EGR cooler 19 becomes. The EGR cooler 19 may, for example, be connected to a cooling circuit 20, which in turn may be coupled to a cooling circuit, not shown, of the internal combustion engine 1 for cooling the engine block 2 heat transfer or may form part of it. Furthermore, the EGR system 15 has a

Exhaust gas recirculation valve 21, which can also be referred to as EGR valve 21 below. In the example, the EGR valve 21 is disposed in the EGR passage 16 upstream of the EGR cooler 19. It is also possible to arrange the EGR valve 21 downstream of the EGR cooler 19 in the EGR passage 16. The EGR valve 21 may also be integrated in the EGR cooler 19 on the input side or on the output side.

The internal combustion engine 1 shown here is charged. For this purpose, it has a charging device 22, which in the preferred example shown by a

Exhaust gas turbocharger is formed, which is also referred to below with 22. With the help of the charging device 22 and the exhaust gas turbocharger 22, the

Pressure level in the fresh air, which is supplied via the fresh air system 4 to the combustion chambers 3, are increased. As a result, the mass flow and thus the power density of the internal combustion engine 1 can be increased. In the example shown, the charging device is configured as an exhaust gas turbocharger 22, which has a compressor 23 arranged in the fresh air system 5 or in its fresh air line 6 and a turbine 24 connected thereto which is arranged in the exhaust system 10 or in the exhaust pipe 11 thereof. In the fresh air system 5 or in the fresh air line 6 may optionally downstream of the compressor 23 a

Intercooler 25 may be arranged, which is preferably connected to a cooling circuit 26. Also, this cooling circuit 26 may, for example, be coupled to the aforementioned cooling circuit of the internal combustion engine 1 for cooling the engine block 2 heat transfer or form part of it. In the example, also a purely exemplary throttle valve 27 is shown in the fresh air system 5 z. Ex. In the fresh air line 6 is arranged, downstream of the charge air cooler 25 and upstream of the fresh air manifold 8. Likewise, the throttle 27 may be integrated on the input side into the fresh air manifold 8. Furthermore, in principle, a throttle-free design of the

Fresh air system 5 conceivable.

In the example, the exhaust system 10 optionally has an exhaust throttle 28, which is arranged in the exhaust pipe 11 downstream of the removal point 17. With the help of such an exhaust throttle 28, if necessary, the pressure in the exhaust gas upstream of the exhaust throttle 28 can be increased to the pressure difference between

Extraction point 17 and discharge point 18 to enlarge. This pressure difference drives the recirculated exhaust gas. Depending on the operating state of the internal combustion engine 1, it may be necessary with the aid of the exhaust throttle 28 a certain

To generate back pressure in order to set a desired exhaust gas recirculation rate or short EGR rate.

The internal combustion engine 1 is also equipped with a filter element 29 which serves to filter out particles entrained in the recirculated exhaust gas. This filter element 29 is arranged in the EGR line 16 downstream of the EGR cooler 19. Thus, the filter element 29 is only cooled

subjected to recirculated exhaust gas, whereby the filter element 29

can be realized comparatively inexpensive. However, it is particularly advantageous in this arrangement that the filter element 29 has a comparatively low flow resistance for a relatively cold exhaust gas flow, while it has a comparatively high flow resistance for a relatively hot exhaust gas flow. In the preferred embodiment shown here, in the EGR line 16 downstream of the filter element 29 also a mist eliminator 30 is arranged, with the aid of drops or Droplets can be separated from the exhaust gas flow. Droplets can be generated in the exhaust gas flow, especially downstream of the EGR cooler 19 by condensation, the filter element 29 being particularly suitable for forming condensate and bringing it together to form droplets.

Fig. 1 also shows a preferred embodiment in which the

Filter element 29 and the droplet 30 are arranged in a common housing 31, namely in a filter housing 31 of an exhaust gas recirculation filter 32. This exhaust gas recirculation filter 32 will be explained in more detail below with reference to FIG. 2 and may also be referred to below as EGR filter 32.

With reference to FIG. 1, it is worth mentioning that the EGR filter 32 is installed in the EGR passage 16 so that in this installation state

Exhaust gas flow or its exhaust gas flow direction, which is indicated in Fig. 2 by an arrow 33, in the filter housing 31 is perpendicular to the direction of gravity, which is indicated in Fig. 2 by an arrow 34.

Correspondingly to FIGS. 2 to 5, the EGR filter 32 accordingly has the filter housing 31, in which the filter element 29 and downstream thereof

Droplet 30 are arranged. In order to be able to install the EGR filter 32 particularly easily in the EGR line 16, the filter housing 31 according to Flg. 2 an inlet flange 35 and an outlet flange 36, with which the filter housing 31 can be screwed to corresponding mating flanges of the EGR line 16. For this purpose, corresponding screw bushes 37 may be provided on the respective flange 35, 36, of which in Fig. 2, however, only one is recognizable. Furthermore, the flanges 35, 36 are equipped with seals 38. According to FIGS. 2 to 5, a sump 39 is also formed in the filter housing 31. The sump 39 is in the installed state with respect to

Direction of gravity 34 below or at the lower end of the Tropfenabscheiders 30 and extends in the example below the filter element 29. The sump 39 is used for collecting liquid, which with the aid of

Droplet 30 has been separated from the exhaust gas.

Furthermore, the EGR filter 32 shown in FIG. 2 is equipped with a heater 40, by means of which the sump 39 or at least the liquid collected in the sump 39 can be heated. With the help of the heater 40, the liquid collected in the sump 39 can be heated as needed so far that it again evaporated and entrained with the exhaust gas flow 33 or from the

Filter housing 31 can be removed.

Suitably, the heater 40 has at least one PTC element 41.

Known, takes in such a PTC element 41 of the electric

Resistance proportional to the temperature, in particular, it is possible to design such a PTC element 41 so that a certain

Target temperature is largely accurately adjustable, without requiring a complex control of the PTC element 41 supplied current is required. The closer the PTC element 41 approaches the target temperature to be set, the greater will be its electrical resistance and the lower will be

Electricity consumption and thus also its heating capacity.

In the example shown, the heater 40 is arranged on the filter housing 31 so that it is a bottom 42 of the sump 39 can be heated, which is in the installation position of the EGR filter 32 shown below. 2 shows a preferred embodiment in which the heater 40 with respect to the rest of the EGR filter 32, a separate component or

Assembly forms, which is attached to the filter housing 31. In particular, the filter housing 31 has a heater receptacle 43, in which the heater 40 is installed.

The embodiments of the EGR filter 32 shown in FIGS. 3 to 5 can also optionally be equipped with such a heater 40.

The mist eliminator 30 is equipped in the example of FIG. 2 with a drainage device 44. In the example, the drainage device 44 is formed by a with respect to the direction of gravity 34 at the lower end of the Tropfenabscheiders 30 arranged curved, in particular cylinder-segment-shaped, wall containing a plurality of passage openings 45, with respect to the

Direction of gravity 34 down and thus the sump 39 are open. Thus, liquid accumulating inside the drainage device 44 or inside the mist eliminator 30 may be collected at the bottom of the drainage device 44 and fed through the openings 45 to the sump 39.

The embodiments of the EGR filter 32 shown in FIGS. 3 to 5 can also optionally be equipped with such a drainage device 44.

In the examples of Flg. 2 to 5, the sump 39 is formed by a trough-shaped recess 46, which is formed in the interior of the filter housing 31 and which is open with respect to the direction of gravity 34 upwards and disposed below the Tropfenabscheiders 30. In the example, the depression 46 or the sump 39 is dimensioned in the opposite direction to the exhaust gas flow direction 33 via the droplet separator 30, so that the sump 39 or the depression 46 also extends over a substantial portion of the filter element 29. The filter element 29 may have at its, the droplet 30 facing the axial end of a bottom 49, for example, for the

Exhaust gas flow 33 may be configured impermeable, so that the

Exhaust gas flow 33 exclusively through a cylindrical wall 47 of the

Filter element 29 must flow radially to flow through the filter element 29. This results in a direct flow admission to an inner side 48 of the filter housing 31, as a result of which droplet formation can also be observed on this inner side 48. Likewise, the filter element 29 at its the muck 30 facing bottom 49 for the

Exhaust gas flow 33 be permeable.

In any case, located in the embodiments shown here within the filter housing 31 downstream of the Tropfenabscheiders 30, a guide collar 50 which protrudes axially against the exhaust gas flow direction 33 from the filter housing 31. The guide collar 50 is preferably in the circumferential direction

closed circumferentially designed. He is at the exit end of the

Filter housing 31 is positioned so that liquid, which moves along the inside 48 of the filter housing 31 in the exhaust gas flow direction 33, collects on the guide collar 50 and is discharged in the direction of the sump 39. The guide collar 50 forms between itself and the inside 48 of the

Filter housing 31 an annular groove in which the liquid can collect and flows due to gravity to the sump 39 out.

In the examples shown, the mist eliminator 30 is designed as a lamella separator, which is arranged parallel to one another and perpendicular to the one in FIG. 2

Exhaust flow direction 33 arranged fins 51 has. The fins 51 have at least in the embodiments of FIGS. 2 and 3 in the exhaust gas flow direction 33, a wave profile 52, which the recording and Deposition of liquid drops favors. Furthermore, each louver 51 has at least one collecting channel 53 which extends in the direction of gravity 34 and which leads the separated liquid to the drainage device 44 in the embodiment shown in FIG. 2 and directly to the sump in the embodiments shown in FIGS. 3 to 5 39 feeds. The respective

Collecting channel 53 is in this case formed in each case by an L-shaped or V-shaped profile body, which is opposite to the respective lamella 51

Exhaust flow direction 33 protrudes.

Suitably, the filter housing 31 is made of plastic. This is possible since it is located downstream of the exhaust gas recirculation cooler 19 and is therefore exposed to comparatively cool exhaust gases.

The filter element 29 has a filter material, which preferably consists of a

Lattice structure exists whose mesh size can be less than 100 pm. It may be a metallic lattice structure or a lattice structure made of plastic.

The following description refers mainly to Figs. 3 to 5. The additionally mentioned features can however also be realized in the embodiment shown in FIG.

Referring to FIGS. 3 to 5 may be provided a drain opening 54 which is fluidly connected to the sump 39 to lead out the accumulated in the sump 39 liquid from the filter housing 31, for example directly into an environment of the exhaust system, optionally in conjunction with a suitable valve device. This drain opening 54 may be expediently arranged in the region of the filter element 29, in particular radially thereto. Optionally, as shown in FIG. 4 and 5 between the drain opening 54 and the filter element 29th a partition 55 may be arranged to provide a direct flow of the

Drain opening 54 to avoid and on or flow through the

Droplet 30 to favor. Further, as shown in FIGS. 4 and 5, a transverse wall 56 may divide the sump 39 into a drainage space 57 fluidly connected to the drainage opening 54 and a collecting space 58. The

Transverse wall 56 is designed to be permeable to the separated liquid, for example by means of at least one passage opening 59 which the

Drainage space 57 fluidly connects through the transverse wall 56 with the collecting space 58. Also, this transverse wall 56 prevents direct flow of the inlet region of the drain opening 54 and thus supports an arrival or flow through the Tropfenabscheiders 30, which improves its efficiency.

The fins 51 have a direction indicated by a double arrow

Slat longitudinal direction 60, with which they are oriented in the exhaust gas flow direction 33, and indicated by a double arrow

Slat transverse direction 61, with which they protrude into the flow path of the exhaust gas. It may be expediently provided that the lamellae 51 are arranged with their lamella transverse direction 61 inclined relative to the direction of gravity 34, wherein it can be seen in the examples that the lamellae 51 are inclined with respect to the direction of gravity 34 in such a way that they come from or to the filter element 29, namely, with respect to the bottom 49 thereof have a distance 62 which is measured in the Abgaströmungsrichtung 33 and which increases in the direction of gravity 34. In addition or as an alternative to the inclination of the transverse Lammellenrichtung 61 may be provided as shown that the fins 51 are inclined with their slats longitudinal direction 60 relative to the exhaust gas flow direction 33. The inclination or setting of the fins 51 with respect to the exhaust gas flow direction 33 with respect to their longitudinal direction 60 or

Transverse direction 61 favors the separation effect, since the employment in the longitudinal direction 60 inevitably to a deflection or deflection of the Exhaust gas flow leads to the respective blade 51, so that entrained

Liquid droplets in any case meet against such a blade 51 and accumulate on it, while the inclination in the transverse direction 61 causes the exhaust gas flow drives the attached to the fins 51 liquid droplets along the lamella transverse direction 61 and so the discharge of

supported liquid supported.

Suitably, the fins 51 may extend according to the embodiment shown in FIG. 5 into the sump 39, resulting in a

particularly simple construction leads.

Furthermore, in all embodiments shown here, FIGS. 2 to 5

provided that the slats 51 are configured as a monolithic slat block 63, the one connecting the slats 51 together

Plate carrier 64 includes. As a result, the slats 51 can be inserted into the filter housing 31 in a particularly simple manner, namely as a unit in the form of the slat block 63.

According to the embodiments of Figs. 3 to 5, the monolithic

Lamella block 63, the partition 55 and / or the transverse wall 56 include.

According to FIGS. 2 to 5, the filter housing 31 can have an exhaust gas inlet 65 and axially aligned with an exhaust gas outlet 66. This gives the EGR filter 32 a comparatively low flow resistance. In this case, the filter element 29 may be arranged coaxially with the exhaust gas inlet 65 and the exhaust gas outlet 66, which likewise favors a low flow resistance. In the embodiment shown in FIG. 2, the filter housing 32 as a whole is configured as a monolith, preferably of plastic, from the inlet 65 to the outlet 66. In contrast, FIGS. 3 to 5 show embodiments in which the filter housing 32 has a monolithic inlet block 67, which has the exhaust gas inlet 65 and can be made in particular of plastic, and a monolithic outlet block 68, which has the exhaust gas outlet 66 and in particular Plastic can be made. In the

Embodiment according to FIG. 5, the inlet block 67 is directly on

Outlet block 68 attached and in contact with this. A corresponding

Axial seal between inlet block 67 and outlet block 68 is not shown; only one intended, unspecified

Receiving groove. In contrast, in the embodiments shown in FIGS. 3 and 4, an additional monolithic intermediate block 69 is provided, which is arranged axially between the inlet block 67 and the outlet block 68. In addition, the intermediate block 69 between the inlet block 67 and the outlet block 68 may be axially braced, whereby the intermediate block 69 is fixed by this tension on the filter housing 32 and is integrated therein. Suitably, the aforesaid drainage opening 54 may be formed in the intermediate block 69 (FIGS. 3 and 4) or in the inlet block (FIG. 5). Corresponding grooves and associated axial seals are not specified.

Furthermore, the droplet separator 30 may be arranged in a separation chamber 70 of the filter housing 31, which merges via a cross-sectional reduction 71 into the exhaust gas outlet 66. In this way, can be kept substantially constant despite filter element 29 and droplet 30 within the filter housing 31 of the flow-through bare section in order to avoid an excessive pressure increase in the flow through the EGR filter 32. Conveniently, at least one pressure relief opening 72 can now be provided, which the Separating chamber 70 through the cross-section reduction 71 fluidly connects to the exhaust gas outlet 66. It bypasses the respective

Pressure relief opening 72 the guide collar 50th

The filter element 29 is expediently designed as a mechanically filtering filter element 29, that is, by a mesh size or pore size of his

Filter material for the exhaust gas permeable and impermeable to the particles to be deposited. For example, the filter element 29 may comprise a filter material of a grid structure 73 which is attached to an annular flange 74, via which the filter element 29 is attached to the filter housing 31. It can be provided according to FIGS. 3 and 4, that the annular flange 74 axially braced axially between the intermediate block 69 and the inlet block 67 and thereby secured to the filter housing 31.

Claims

claims

1 . Exhaust gas recirculation filter for installation in an external exhaust gas recirculation line (16) of an internal combustion engine (1), in particular of a motor vehicle,

 - With a filter housing (31),

 with a filter element (29) arranged in the filter housing (31), which filters out particles entrained in the recirculated exhaust gas,

characterized by a in the filter housing (31) downstream of the filter element (29) arranged droplet separator (30).

2. Exhaust gas recirculation filter according to claim 1,

characterized,

in that a sump (39) for collecting separated liquid is formed in the filter housing (31).

3. exhaust gas recirculation filter according to claim 2,

characterized,

in that a heater (40) is provided for heating the sump (39) and / or the liquid collected in the sump (39).

4. exhaust gas recirculation filter according to claim 3,

characterized,

in that the heater (40) has at least one PTC element (41).

5. Exhaust gas recirculation filter according to claim 3 or 4, characterized,

the heater (40) heats a bottom (42) of the sump (39) lying below in the installed position of the exhaust gas recirculation filter (32) in the direction of gravity (34).

6. exhaust gas recirculation filter according to one of claims 3 to 5,

characterized,

in that the heater (40) is a separate component that fits into an am

Filter housing (31) formed heating receptacle (43) is installed.

7. Exhaust gas recirculation filter according to one of claims 2 to 6,

characterized,

a drain opening (54) is provided, which is fluidically connected to the sump (39).

8. exhaust gas recirculation filter according to claim 7,

characterized,

the drain opening (54) is arranged in the region of the filter element (29).

9. exhaust gas recirculation filter according to claim 7 or 8,

characterized,

that between the drain opening (54) and the filter element (29) has a

Partition (55) is arranged.

10. Exhaust gas recirculation filter according to one of claims 7 to 9,

characterized,

a transverse wall (56) subdivides the sump (39) into an outflow space (57) fluidically connected to the discharge opening (54) and a collecting space (58), the transverse wall (56) being permeable to the separated liquid, for example by means of at least a passage opening (59), which fluidly connects the discharge space (57) through the transverse wall (56) with the collecting space (58).

1 1. Exhaust gas recirculation filter according to one of claims 2 to 10,

characterized,

in that the droplet separator (30) has a drainage device (44) which supplies separated liquid to the sump (39).

12. exhaust gas recirculation filter according to one of claims 2 to 1 1,

characterized,

in that the sump (39) is formed by a depression (46) formed in the interior of the filter housing (31), which in the installation position of the exhaust gas recirculation filter (32) is arranged below the mist eliminator (30) in the direction of gravity (34) and open at the top.

13. exhaust gas recirculation filter according to one of claims 2 to 12,

characterized,

the filter housing (31) has, downstream of the droplet separator (30), a guide collar (50) projecting counter to the exhaust gas flow direction (33), the liquid which extends along an inner side (48) of the

Filter housing (31) in the exhaust gas flow direction (33) moves, collects and towards the sump (39) discharges.

14. exhaust gas recirculation filter according to one of claims 2 to 13,

characterized,

that the sump (39) also extends over a substantial portion of the

Filter element (29) extends.

15. exhaust gas recirculation filter according to one of claims 1 to 14, characterized,

the droplet separator (30) is configured as a lamella separator, which has a plurality of mutually parallel and in the flow path of the

Having arranged exhaust gas flow lamellae (51).

16. exhaust gas recirculation filter according to claim 15,

characterized,

in that the lamellae (51) have a wave profile (52) in the exhaust gas flow direction (33).

17. exhaust gas recirculation filter according to claim 15 or 16,

characterized,

in that each lamina (51) has at least one collecting trough (53) oriented in the direction of gravity (34), which discharges the separated liquid.

18. exhaust gas recirculation filter according to claim 17,

characterized,

in that the droplet separator (30) has a drainage device (44), wherein the respective collecting channel (53) separates the separated liquid from the liquid

Drainage device (44) leads.

19. exhaust gas recirculation filter according to claims 2 and 18,

characterized,

in that the drainage device (44) supplies the separated liquid to the sump (39).

20. Exhaust gas recirculation filter according to one of claims 15 to 19,

characterized, in that the lamellae (51) have a lamellae longitudinal direction (60) with which they are oriented in the exhaust gas flow direction (33) and a lamella transverse direction (61) with which they protrude into the flow path of the exhaust gas, the lamellae (51) with their Slat transverse direction (61) opposite to

Gravity direction are arranged inclined.

21. Exhaust gas recirculation filter according to claim 20,

characterized,

in that the lamellae (51) are inclined relative to the direction of gravity in such a way that they have a spacing (62) which increases in the direction of the force of gravity from the filter element (29).

22. Exhaust gas recirculation filter according to one of claims 15 to 21,

characterized,

in that the lamellae (51) have a lamellae longitudinal direction (60) with which they are oriented in the exhaust gas flow direction (33) and a lamella transverse direction (61) with which they protrude into the flow path of the exhaust gas, the lamellae (51) with their Slat longitudinal direction (60) compared to

Exhaust flow direction (33) are inclined.

23. exhaust gas recirculation filter according to one of claims 15 to 22,

characterized,

in that the lamellae (51) extend into the sump (39) according to claim 2.

24. exhaust gas recirculation filter according to one of claims 15 to 23,

characterized, in that the lamellae (51) are designed as a monolithic lamella block (63) which comprises a lamella carrier (64) interconnecting the lamellas (51).

25. Exhaust gas recirculation filter according to claim 24,

characterized,

the fin block (63) comprises the dividing wall (55) according to claim 9 and / or the transverse wall (56) according to claim 10.

26. Exhaust gas recirculation filter according to one of claims 1 to 25,

characterized,

that the filter housing (31) is made of plastic.

27. exhaust gas recirculation filter according to one of claims 1 to 26,

characterized,

in that the filter element (29) has a filter material made of a lattice structure which in particular has a mesh width of less than 100 μm.

28. Exhaust gas recirculation filter according to one of claims 1 to 27,

characterized,

in that the filter housing (31) has an exhaust gas inlet (65) and axially aligned therewith an exhaust gas outlet (66), the filter element (29) being arranged coaxially with the exhaust gas inlet (65) and exhaust gas outlet (66).

29. Exhaust gas recirculation filter according to one of claims 1 to 28,

characterized,

in that the filter housing (31) has a monolithic inlet block (67) which has an exhaust gas inlet (65) and a monolithic outlet block (68) which has an exhaust gas outlet (66).

30. exhaust gas recirculation filter according to claim 29,

characterized,

a monolithic intermediate block (69) is provided which is arranged and / or braced axially between the inlet block (67) and the outlet block (68).

31. Exhaust gas recirculation filter according to one of claims 1 to 30,

characterized,

the drain opening (54) according to claim 7 is formed in the intermediate block (69).

32. Exhaust gas recirculation filter according to one of claims 1 to 31,

characterized,

the droplet separator (30) is disposed in a separation chamber (70) of the

Filter Housing (31) is arranged, which merges via a cross-sectional reduction (71) in an exhaust gas outlet (66), wherein at least one

Pressure relief port (72) is provided, which fluidly connects the separation chamber (70) through the cross-sectional reduction (71) with the exhaust gas outlet (66).

33. exhaust gas recirculation filter according to one of claims 1 to 32,

characterized,

the filter element (29) is designed as a mechanically filtering filter element.

34. exhaust gas recirculation filter according to one of claims 1 to 33,

characterized, in that the filter element (29) has a filter material made of a grid structure (73) which is fastened to an annular flange (74) via which the filter element (29) is fastened to the filter housing (31),

35. exhaust gas recirculation filter according to claims 30 and 34,

characterized,

in that the annular flange (74) is clamped axially between the intermediate block (69) and the inlet block (67) and is thereby fastened to the filter housing (31).

36. Internal combustion engine, in particular of a motor vehicle,

 - With at least one fresh air line (6) for supplying fresh air

 Cylinders (4) of the internal combustion engine (1),

 - With at least one exhaust pipe (1 1) for discharging exhaust gas from the cylinders (4),

 - With at least one exhaust gas recirculation line (16) which fluidly connects the exhaust pipe (1 1) with the fresh air line (6),

 with an exhaust gas recirculation cooler (19) arranged in the exhaust gas recirculation line (16),

 with a filter element (29) arranged in the exhaust gas return line (16) for filtering out particles entrained in the recirculated exhaust gas, characterized

in that the filter element (29) in the exhaust gas recirculation line (16) downstream of

Exhaust gas recirculation cooler (19) is arranged.

37. Internal combustion engine according to claim 36,

characterized,

in that a charging device (23) is arranged in the fresh air line (6), wherein the exhaust gas return line (16) upstream of the charging device (23) adjoins the

Fresh air line (6) is connected.

38. Internal combustion engine according to claim 37,

characterized,

in that the charging device is formed by a compressor (23) of an exhaust-gas turbocharger (22), the turbine (24) of which is arranged in the exhaust-gas line (11), the exhaust-gas recirculation line (16) being located downstream of the turbine (24)

Exhaust pipe (1 1) is connected.

39. Internal combustion engine according to one of claims 36 to 38,

characterized,

in that a droplet separator (30) is arranged downstream of the filter element (29) in the exhaust gas recirculation line (16).

40. Internal combustion engine according to claim 39,

characterized,

in that the filter element (29) and the droplet separator (30) are arranged together in a filter housing (31) of an exhaust gas recirculation filter (32) according to one of claims 1 to 35.

41. Internal combustion engine according to claim 40,

characterized,

in that the exhaust gas recirculation filter (32) is installed in the exhaust gas recirculation line (16) in such a way that the exhaust gas flow direction (33) in the filter housing (31) runs perpendicular to the direction of gravity (34).

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