DE102015212788A1 - Catalytically active particle filter - Google Patents

Abstract

The invention relates to a catalytically active particulate filter (400 ') comprising gas-permeable filter substrate walls (FW), which has a filter body with at least one inlet and outlet channel (K21, K2) arranged adjacent to a flow direction (R) of an exhaust gas through the particulate filter (400'). K12) form, wherein the inflow channel (K21) downstream and the outflow channel (K12) are closed gas-tight upstream. It is provided that the filter substrate wall (FW) of the inflow channel (K21) has a two-layer catalytic layer structure (II; II-A, II-B, II-C, II-D) at least in an inlet region of the exhaust gas into the particle filter (400 ') ) with a first catalytic layer (1) and a second catalytic layer (2), while the filter substrate wall (FW) of the outflow channel (K12) at least in an outlet region of the exhaust gas from the particulate filter (400 ') has a single-layered catalytic layer structure ( I, IA, IB) with only one catalytic layer (1).

Description

The invention relates to a catalytically active particulate filter, which has gas-permeable filter substrate walls which form a filter body with at least one adjacent to a flow direction of an exhaust gas through the particle filter adjacent inlet and outlet, wherein the inflow channel downstream and the outflow are closed gas-tight upstream, so that the exhaust gas of the inflow channel is forced into the adjacent outflow channel through gas-permeable pores of the filter substrate wall with the deposition of particles on the filter substrate wall.

The publication DE 10 2004 040 549 A1 discloses a catalytically coated particulate filter and a method for its production and its use for removing carbon monoxide, hydrocarbons and soot particles from the exhaust gas of an internal combustion engine, in particular a lean-burned gasoline engine or a diesel engine. It is proposed a catalytic coating containing two catalysts arranged one behind the other. The first catalyst is located in the gas inlet region of the filter and contains a palladium / platinum catalyst. The second catalyst is arranged behind it and preferably contains only platinum as the catalytically active component. The combination of these two catalysts is said to provide the coated filter with good aging stability and resistance to sulfur poisoning.

The publication EP 2 042 225 A1 describes an operating with predominantly stoichiometric air / fuel mixture internal combustion engine, the exhaust gas containing in addition to the gaseous pollutants hydrocarbons, carbon monoxide and nitrogen oxides also the finest particles. A catalytically active particulate filter, an exhaust gas purification system and a process for purifying the exhaust gases of predominantly stoichiometrically operated internal combustion engines are presented, which are suitable for removing particulates from the exhaust gas in addition to the gaseous pollutants CO, HC and NO _x . The particle filter contains a filter body and a two-layer catalytically active coating. The first layer is in contact with the incoming exhaust gas, the second layer with the outflowing exhaust gas. Both layers contain alumina. The first layer is palladium-containing. The second layer contains, in addition to rhodium, an oxygen-storing cerium / zirconium mixed oxide.

From the publication EP 2 623 183 A1 a catalytically active particulate filter is known, which is suitable for use in an exhaust gas purification system for diesel engines. The particulate filter removes particulate soot from the exhaust and is also effective to oxidize carbon monoxide and hydrocarbons and convert nitrogen monoxide at least partially to nitrogen dioxide. The particle filter comprises a filter body and two catalytically active coatings containing platinum and palladium or platinum or platinum and palladium, wherein the platinum content of the second catalytically active coating is higher than the platinum content of the first catalytically active coating.

The publication DE 60 2005 005 022 T describes a three-way catalyst for purifying exhaust gases from stoichiometric gasoline engines. The three-way catalyst should be equally applicable to so-called lean-burn engines and diesel engines. The catalyst has a catalytic coating on a honeycomb carrier, the honeycomb carrier having an upstream end and a downstream end and a plurality of flow channels leading from the upstream end to the downstream end, the catalytic coating comprising at least one catalytically active noble metal component having a continuously varying concentration profile along the axis of the honeycomb carrier. Here, the honeycomb carrier is in three contiguous regions with a low concentration in the first or upstream region at the inlet side of the carrier and with a steep rise to a peak concentration in the second or middle region and a third concentration in the third or downstream region, which is equal to or smaller than the peak concentration in the second region.

The pamphlets DE 10 2004 040 549 A1 . EP 2 042 225 A1 and DE 60 2005 005 022 T deal with the problem of thermal damage of the catalysts mentioned there as a function of their life, that is with the thermal aging stability.

The pamphlets DE 10 2004 040 549 A1 . EP 2 042 225 A1 and EP 2 623 183 A1 deal with catalytically coated particle filters, so-called four-way catalysts.

Of the last-mentioned documents describes the EP 2 042 225 A1 a solution to the thermal aging stability of a particulate filter in an emission control system of a gasoline-powered Improve combustion engine. In the publication EP 2 042 225 A1 It is stated that there are significant differences in the exhaust gas temperature, the exhaust gas composition and the nature of the particulate matter in removing particulates from the exhaust gas of predominantly stoichiometric gasoline engines. Gasoline-powered internal combustion engines have significantly higher exhaust gas temperatures than lean-burn engines and diesel-powered internal combustion engines.

Therefore, a catalytically coated particulate filter, which should be suitable for purifying exhaust gases of predominantly stoichiometrically operated internal combustion engines, must be distinguished above all by high thermal aging stability.

The other pamphlets DE 10 2004 040 549 A1 and EP 2 623 183 A1 describe known catalytically activated diesel particulate filters, which generally do not meet the aforementioned requirements. The publication EP 2 042 225 A1 thus constitutes the closest prior art to the Applicant.

The invention is based on the object, the thermal aging stability of a catalytically coated particulate filter for a predominantly stoichiometric gasoline-powered internal combustion engine to remove carbon monoxide, unburned hydrocarbons and nitrogen oxides and fine dust particles from the exhaust to improve.

In addition, a catalytic particle filter is being sought which, in addition to the improved thermal aging stability, complies with the current and future emission standards Euro5 standard and Euro6 standard.

The starting point of the invention is a catalytically active particulate filter, in particular for an internal combustion engine, comprising gas-permeable filter substrate walls which form a filter body with at least one adjacent to a flow direction of an exhaust gas through the particle filter adjacent inlet and outlet, wherein the inflow channel downstream and the outflow on the inflow side are closed gas-tight.

According to the invention, it is provided that the particle filter is catalytically coated: the filter substrate wall of the inflow channel has a two-layered catalytic layer structure, in particular a precisely two-layered catalytic layer structure, with a first catalytic layer and a second catalytic layer, at least in an inlet region of the exhaust gas into the particle filter. The advantage is that two-layered catalytic layer structures are more resistant to aging than single-layer layer structures with respect to the temperatures acting on the respective layer structure during operation of the particle filter.

The particulate filter is preferably a gasoline particulate filter for a gasoline engine.

The invention proposes several different variants of the coating type of the filter substrate walls of a catalyst package.

In a first embodiment, the layers of the two-layer catalytic layer structure are formed on the filter substrate wall.

In a second embodiment, the layers of the two-layer catalytic layer structure are formed in the filter substrate wall.

In a third embodiment, the layers of the two-layer catalytic layer structure are partially formed in and on the filter substrate wall.

In a preferred embodiment, it is provided that the filter substrate wall of the inflow channel in the inlet region of the exhaust gas into the particle filter having the two-layer catalytic layer structure with the first catalytic layer and the second catalytic layer, while the filter substrate wall of the outflow channel in an outlet region of the exhaust gas from the particle filter single-layer catalytic layer structure, in particular has a single-layer catalytic layer structure, with only one catalytic layer.

The invention also proposes different embodiments of the type of coating of the filter substrate walls of the catalyst package for this aforementioned preferred embodiment.

In a fourth embodiment variant, the layers of the two-layer catalytic layer structure and the layer of the single-layer catalytic layer structure are formed on the filter substrate wall.

In a fifth embodiment variant, the layers of the two-layer catalytic layer structure and the layer of the single-layer catalytic layer structure are formed in the filter substrate wall.

In a sixth embodiment, the layers of the two-layer catalytic layer structure and the layer of the single-layer catalytic layer structure are partially formed in and on the filter substrate wall.

In a seventh embodiment variant, the layers of the two-layer catalytic layer structure are formed on the filter substrate wall and the layer of the single-layer catalytic layer structure is formed in the filter substrate wall.

In an eighth embodiment, the layers of the two-layer catalytic layer structure on the filter substrate wall and the layer of the single-layer catalytic layer structure are partially formed in and on the filter substrate wall.

In a ninth embodiment variant, the layers of the two-layer catalytic layer structure in the filter substrate wall and the layer of the single-layer catalytic layer structure are formed on the filter substrate wall.

In a tenth embodiment, the layers of the two-layer catalytic layer structure in the filter substrate wall and the layer of the single-layer catalytic layer structure are partially formed in and on the filter substrate wall.

In an eleventh embodiment, the layers of the two-layer catalytic layer structure are partially formed in and on the filter substrate wall and the layer of the single-layer catalytic layer structure on the filter substrate wall.

In a twelfth embodiment, the layers of the two-layer catalytic layer structure are partially formed in and on the filter substrate wall and the layer of the single-layer catalytic layer structure in the filter substrate wall.

• • die erste katalytische Schicht eines ersten zweischichtigen Schichtaufbaus Rhodium enthält, während die zweite katalytische Schicht Palladium enthält oder
• • die erste katalytische Schicht eines zweiten zweischichtigen Schichtaufbaus Palladium enthält, während die zweite katalytische Schicht Rhodium enthält oder
• • die erste katalytische Schicht eines dritten zweischichtigen Schichtaufbaus Rhodium enthält, während die zweite katalytische Schicht Platin enthält oder
• • die erste katalytische Schicht eines vierten zweischichtigen Schichtaufbaus Platin enthält, während die zweite katalytische Schicht Rhodium enthält.

It is preferred that the optionally usable two-layer layer structure be provided that

• The first catalytic layer of a first two-layer layer structure contains rhodium, while the second catalytic layer contains palladium or
• The first catalytic layer of a second two-layer layer structure contains palladium while the second catalytic layer contains rhodium or
• The first catalytic layer of a third two-layer layer structure contains rhodium, while the second catalytic layer contains platinum or
• • The first catalytic layer of a fourth two-layer layer structure contains platinum, while the second catalytic layer contains rhodium.

• • die katalytische Schicht eines ersten einschichtigen Schichtaufbaus Palladium und Rhodium enthält oder
• • die katalytische Schicht eines zweiten einschichtigen Schichtaufbaus Platin und Rhodium enthält.

It is preferred that the optionally usable single-layer layer structure be provided that

• The catalytic layer of a first single-layered structure contains palladium and rhodium or
• • contains the catalytic layer of a second single-layer layer structure platinum and rhodium.

In a preferred embodiment, it is provided that the single-layer catalytic layer structure embodied in the outflow channel adjoins without overlap at the two-layer catalytic layer structure designed in the flow channel in the flow direction. The advantage is that consumption of precious metals is kept as low as possible.

In another preferred embodiment, it is provided that the two-layered catalytic layer structure embodied in the inflow channel overlaps with the single-layer catalytic layer structure embodied in the outflow channel in the flow direction. The advantage is that the manufacturing process is simplified, since the layers can overlap more or less during the coating.

It is further preferably provided that the layer length of the two-layer catalytic layer structure executed in the inflow channel is varied in the direction of flow. The variation takes place as a function of a temperature level along the inflow channel and / or a raw emission level of an upstream internal combustion engine and / or the exhaust gas limit values of an exhaust standard to be maintained at the flow-side end of the particulate filter and / or a backpressure of the particulate filter within the exhaust gas purification system applied to the flow-side beginning, wherein the two-layered one no further layer structure follows in the direction of flow in the catalytic layer structure, or the single-layered catalytic layer structure adjoins the two-layer catalytic layer structure without overlapping or overlaps with the two-layer catalytic layer structure.

In particular, it is provided in a preferred embodiment that the two-layered catalytic layer structure embodied in the inflow channel partially or completely overlaps the overlapping zone of the particle filter formed between the downstream end of the inflow channel and the inflow-side end of the outflow channel with the single-layer catalytic layer structure formed in the outflow channel.

Furthermore, according to the invention, in a preferred embodiment, the two-layered catalytic layer structure is formed in the inflow channel as a function of the temperature level along the inflow channel only in a region near the engine of the inflow channel in which a temperature greater than 800 ° C. prevails. That is to say, the layer length of the two-layer catalytic layer structure embodied in the inflow channel is formed in a region of the inflow channel close to the engine, in which, in particular, a temperature greater than 800 ° C. prevails.

According to the invention, it is provided that an exhaust gas purification system for purifying the exhaust gases of a predominantly stoichiometrically operated internal combustion engine comprises a catalytically active particulate filter with features or combinations of features according to this representation.

In a preferred embodiment, the exhaust gas purification system according to the invention is characterized in that the catalytically active particulate filter is arranged in the exhaust gas purification system in a position close to the engine, in particular in front of a three-way catalytic converter and / or in the engine compartment.

In the context of the present invention, the term "close to the engine" means a distance between the cylinder outlet of the internal combustion engine and the end face of the exhaust gas treatment device of at most 120 cm, in particular at most 100 cm, preferably at most 80 cm. In a concrete embodiment, the distance is about 75 cm. A close-coupled arrangement means, in particular, that the exhaust gas treatment device is arranged in the engine compartment and / or accommodated on the internal combustion engine ("closed-coupled"). In this way, the waste heat of the internal combustion engine can be used to achieve the operating temperatures of the catalysts in the exhaust gas treatment device.

The invention will be explained below with reference to the accompanying drawings. Show it:

1 in a schematic representation, two channels of a known three-way catalyst;

2 in a schematic representation of two channels of a known four-way catalyst;

3 in a schematic representation, two channels of a four-way catalyst according to the invention;

4 a section through a catalyst package of the four-way catalyst according to the invention according to 3 ; and

5 a representation of the arrangement of the four-way catalytic converter according to the invention behind an internal combustion engine within an exhaust gas purification system.

1 shows very schematically two channels K; K1, K2 of a known three-way catalyst 300 comprising a plurality of such channels K1, K2 in a catalyst packet, which are usually rectilinear. On so-called substrate walls W, through which the channels are formed, noble metals are applied in two layers, which are suitable for the catalytic reactions according to the following three known reaction mechanisms in the three-way catalyst 300 to care.

The pollutants carbon monoxide, unburned hydrocarbons and nitrogen oxides are removed from the exhaust gas according to the following equations: 2 CO + O ₂ → 2 CO ₂ C _m H _n + (m + n 4) O ₂ → m CO ₂ + n / 2 H ₂ O 2 NO + 2 CO → N ₂ + 2 CO ₂

The precious metals are applied to the substrate walls W as so-called catalytic coatings. A catalytic coating is also referred to as washcoat.

The walls of the substrate walls W are provided with at least one active, porous washcoat layer. It is / are applied as a viscous solution, also called washcoat slurry or washcoat solution, then dried, and then calcined in an oven.

The respective washcoat layer consists predominantly of aluminum oxide, as well as other oxide additives and rare earths. As catalytically active material, platinum (Pt) and rhodium (Rh) are predominantly added in addition to palladium (Pd). The noble metals mentioned are brought into solution in the form of aqueous salt solutions with the washcoat slurry, for example, and then applied and dried so that a washcoat layer is produced on the substrate walls W. The noble metals mentioned are finally finely dispersed in the applied on the substrate walls W washcoat layer.

According to 1 In particular, it is known that the walls of the substrate walls W of the channels K1, K2 in the flow direction R from the inlet side of the catalyst package to the outlet side of the catalyst over the entire channel length of the channels K1, K2 monolayer with a washcoat layer 1 or two-ply with two washcoat layers 1. and Second are provided.

Single-layered design:

One with the cardinal number " 1 "Defined washcoat layer means in the following description that only a washcoat layer is present on a wall of the respective substrate wall W of a channel K1, K2.

Two-layer design:

In the following description means that one with the atomic number " 1. "Defined first washcoat layer is located directly on the substrate wall W of the respective channel K1, K2 and one with the atomic number" Second "Designated washcoat layer on the first layer 1. of the respective channel K1, K2.

In the various layer structures explained below, only the precious metals responsible for the catalytic reaction and predominantly used in the respective layer are discussed. It is understood that the layers, as explained above, consist predominantly of alumina and other oxide additives and rare earths and are provided in a predeterminable amount with the following precious metals.

Single-layered coatings in all channels K (K1, K2) uniformly: Name of the layer structure layer Contained precious metal layer structure IA : 1 Palladium and rhodium (CO + CmHn + NOx) or layer structure IB : 1 Platinum and rhodium (CO + CmHn + NOx)

Two-layer laminar structure in all channels K (K1, K2) uniformly: Name of the layer structure layer Contained precious metal layer structure II-A : 1. Rhodium (NOx) Second Palladium (CO + CmHn) or layer structure II-B : 1. Palladium (CO + CmHn) Second Rhodium (NOx) or layer structure II-C : 1. Rhodium (NOx) Second Platinum (CO + CmHn) or layer structure II-D : 1. Platinum (CO + CmHn) Second Rhodium (NOx)

In the layer structures IA and IB be in one shift 1 The catalytic coating oxidizes hydrocarbons and carbon monoxide while reducing nitrogen monoxide.

In the layer structures II-A and II-C be in the second layer Second oxidized by the catalytic coating hydrocarbons and carbon monoxide and in the first layer 1. Nitric oxide is simultaneously reduced.

In the layer structures II-B and II-D be in the first layer 1. oxidized by the catalytic coating hydrocarbons and carbon monoxide and in the second layer Second At the same time nitrogen monoxide is reduced to nitrogen dioxide.

The 1 shows for clarity schematically a known two-layered layer structure II a three-way catalyst 300 while a known single-layered with a single-layered layer construction I provided three-way catalyst 300 not shown.

The layers 1. and Second include according to said layer structures II-A to II-D the precious metals rhodium, palladium and platinum.

Not shown is the single-layered layer structure I the well-known three-way catalyst 300 in two alternatives. The mentioned layer structures IA and IB each contain two precious metals of the precious metals rhodium, palladium and platinum in a layer 1.

The layered structures, also referred to as washcoat layers IA and IB such as II-A to II-D the well-known three-way catalysts 300 are performed on the substrate walls W and extend over the entire channel length K1, K2 of the channels of the three-way catalysts 300 ,

The gas flows according to the arrows 1 is shown, within a channel K1, K2 from an inlet side to an outlet side of the catalyst packet.

In 2 is strongly schematized on the basis of two channels K; K21, K12 a well-known four-way catalyst 400 which also includes a plurality of channels K21, K12 in a catalyst packet.

A four-way catalyst 400 is different from the three-way catalyst 300 in that the channels K which are transverse to the flow direction R are closed at each end with so-called plugs S. The adjacent channels K are in the flow direction R each alternately front closed (in 2 left) and closed at the back (in 2 right).

The walls of the substrate walls of the channels K21, K12 of the four-way catalyst 400 are now unlike the three-way catalyst 300 with gas impermeable walls ( 1 ) with gas-permeable walls ( 2 ), whereby as so-called - fourth path particles can be filtered and deposited in the pores of the substrate walls.

The separated particles are in the operation of the internal combustion engine at high temperatures in the exhaust line thus in the four-way catalyst 400 burned to carbon dioxide.

The substrate walls are used in four-way catalysts 400 because of their filtering property also referred to as gas-permeable filter substrate walls FW.

Thus, with a four-way catalyst 400 In addition to carbon monoxide, hydrocarbons and nitrogen oxides and fine dust from the exhaust gas of internal combustion engines are removed.

The exhaust gas flows on the inlet side in those channels K21, which are open at the front and closed at the rear. Since the exhaust gas can not escape through the channel K21 through the arrangement of a plug S at the end of the first channel K21 behind, it is forced through the pores of the filter substrate wall FW in the adjacent channel K12, which closed at the front by a plug S and rear open is. The gas flows as shown in the arrows 2 is shown, via the channels K21, K12 from the inlet side in the so-called inflow channel K21 to the outlet side of the so-called outflow channel K12 of the catalyst package.

In 2 the channel K12 is closed at the front and forms the discharge channel. The exhaust gas will thus flow into the channel K21 as an inflow channel and be forced into the adjacent channel K12 with fine dust separation on the filter substrate wall FW, the reactions taking place in the coatings of the inflow channel K21 and the coatings of the outflow channel K12 taking place corresponding to the selected catalytic coating. Exhaust gas in the inflow channel K21 differs with respect to particulate matter from the exhaust gas in the outflow channel K12 in that the exhaust gas in the outflow channel K12 is largely free of particulate matter.

The catalytic reactions take place in a known four-way catalyst 400 according to 2 with the single-layered layer structure IA or the single-layered layer structure IB in the inflow channel K21 and in the outflow channel K12 instead, from the possible single-layered structures IA or IB it is possible to choose which layer structure is to be used.

Single-layer coatings in all channels K (K21, K12) uniformly: Name of the layer structure layer Contained precious metal layer structure IA : 1 Palladium and rhodium (CO + CmHn + NOx) or layer structure IB : 1 Platinum and rhodium (CO + CmHn + NOx)

In the known four-way catalyst 400 is provided that the respective single-layered layer structure IA or IB on (as in 2 shown) or (not shown) of the filter substrate wall FW of the inflow passage K21 and the outflow K12 is formed.

The respective layer structure IA or IB the Anströmkanals K21 and the outflow K12 is in a known manner only partially, that is not formed over the channel length of the channels K21, K12, as 2 also clarified.

The single-layered layer structure IA or IB within the inflow channel K21 extends in the known four-way catalyst 400 from the inlet side of the catalyst package, for example, to the center M of the catalyst package, wherein the center of the catalyst package is defined as half the length of the catalyst total length of the catalyst package between the inlet side of the catalyst packet and the outlet side of the catalyst package.

The single-layered layer structure IA or IB Within the outflow channel K12 extends in the known four-way catalyst, for example, from the center of the outflow K12 to the outlet side of the respective outflow K12.

With respect to the thermal aging stability is with respect to the previously described two-layered layer structures II-A to II-D the three-way catalysts 300 (according to 1 ) that the Coating the layer structures II-A to II-D only above that for the three-way catalysts 300 usual standard exhaust gas temperatures of 1000 ° C significantly aging.

The single-layer structures described so far IA and IB the four-way catalysts 400 (according to 2 ) age in contrast to the two-layer coating structures II-A to II-D the three-way catalysts 300 (according to 1 ) already at standard exhaust gas temperatures of greater than 800 ° C.

In other words, the two-layered layer structures II-A to II-D the well-known three-way catalysts 300 If the same temperature or the same temperature difference is used, they are more resistant to aging than the single-layer coatings IA and IB the well-known four-way catalysts 400 ,

The negative thermal aging effect of the known single-layer coatings IA and IB the four-way catalysts 400 compared to the three-way catalysts 300 with a two-layer age-resistant layer structure ( 1 and related description) has been accepted so far. The application of the single-layered layer structures IA and or IB on or in the filter substrate wall FW of the known four-way catalysts 400 , according to 2 , namely are opposite to the application of the selected two-layered layer structures II-A to II-D on the substrate wall W of the known three-way catalysts 300 , according to 1 , less expensive.

A first aspect of the invention is the thermal aging stability of the four-way catalysts 400 In order to increase the service life of the catalytic converters, it should be noted at the same time that the required limit values of the current Euro5 standard and the future Euro6 standard of gasoline-fueled internal combustion engines should be met.

To cope with both aspects, the following new inventive structure of a four-way catalyst 400 ' proposed.

A possible new construction of the four-way catalyst 400 ' , in particular its layer structure, is highly schematized analogous to the 1 . 2 and 3 shown.

In addition to this will be in 4 analogous to 3 a catalyst package of the four-way catalyst 400 ' shown in a guided in the flow direction R section. The 3 and 4 are explained below in a synopsis.

Deviating from the prior art, the following layer structures are optionally provided for the respective channels K21 and K12:

Two-layer coating (optional) only in the inflow channels K21. Name of the layer structure layer Contained precious metal layer structure II-A : 1. Rhodium (NOx) Second Palladium (CO + CmHn) or layer structure II-B : 1. Palladium (CO + CmHn) Second Rhodium (NOx) or layer structure II-C : 1. Rhodium (NOx) Second Platinum (CO + CmHn) or layer structure II-D : 1. Platinum (CO + CmHn) Second Rhodium (NOx)

Single-layer coating (optional) only in the outflow channels K12. Designation of the layer structure layer Contained precious metal layer structure IA : 1 Palladium and rhodium (CO + CmHn + NOx) or layer structure IB : 1 Platinum and rhodium (CO + CmHn + NOx)

A four-way catalyst 400 ' According to the invention is in the sectional view in 4 basically structured as follows.

The catalyst 400 ' includes an inlet opening 410 and an exit opening 420 , about which the exhaust gas of the internal combustion engine in the catalyst 400 enters and after its purification in the catalyst 400 ' exits again.

The catalyst 400 ' has a shell 430 on, on the inside of a storage mat 440 is arranged, which is the different expansion behavior of the existing mostly steel sheet shell 430 and compensates for the filter substrate walls FW of the catalyst package consisting of a different material.

The filter substrate walls FW form the channels K; K21, K12, where several channels K; K21, K12 form the illustrated catalyst package. The porous filter substrate walls FW may be formed of ceramic or sintered metal or of ceramic or metallic foam structures.

As explained above, the exhaust gas flows into those channels K21 (inflow channels), which are open at the front and closed at the rear. Since the exhaust gas can not escape through the channels K21 through the arrangement of the plug S at each end of the first channel K21 rear, it is forced through the pores of the filter substrate walls FW in the transverse to the flow direction R adjacent channels K12 (outflow), which closed at the front by a plug S and open at the back. The exhaust gas flows as indicated by the arrows in FIGS 3 to 4 is shown, via the channels K21, K12 from the inlet side in the inflow passage K21 to the outlet side of the outflow K12 of the four-way catalyst 400 ' ,

Each inflow channel K21 and each outflow channel K12 forms a channel length reduced by the width of the respective plug S between the inlet side and outlet side of the catalyst packet.

First embodiment:

The first embodiment is not shown. In the first embodiment, the filter substrate wall FW of the inflow channel K21 at least in an inlet region of the exhaust gas in the particle filter 400 ' a two-layer catalytic layer structure II ; II-A . II-B . II-C . II-D with a first catalytic layer 1. and a second catalytic layer Second on. In the first embodiment, the outflow channel K12 has no coating. In the first embodiment, the layers are the selected two-layer catalytic layer structure II ; II-A . II-B . II-C . II-D formed on the filter substrate wall FW (first embodiment) or in the filter substrate wall FW (second embodiment) or partially in and on the filter substrate wall FW (third embodiment). This advantageously makes it possible to produce the four-way catalyst 400 ' All currently known coating methods with their respective advantages can be used.

The layer length of the two-layer catalytic layer structure selected and executed in the inflow channel K21 II ; II-A . II-B . II-C . II-D is seen in the flow direction R as a function of a temperature level along the inflow channel K21 and / or a raw emission level of an upstream internal combustion engine and / or at the flow-side end of the particulate filter 400 ' to be complied exhaust limits of an exhaust standard and / or applied to the flow-side beginning back pressure of the particulate filter 400 ' within an emission control system 200 varied.

A maximum layer length of 100% of the executed two-layer catalytic layer structure II ; II-A . II-B . II-C . II-D in the inflow channel K21 corresponds to the channel length between the inlet side and outlet side of the catalyst package, which is reduced by the width of the plug S in the inflow channel K12. In order to achieve an economical use of precious metals, the layer length depends on the mentioned boundary conditions shortened executed and is starting from the inlet side into the catalyst packet preferably between 20% and 50% of the total channel length of the inflow channel K21.

Each of the two-layer laminates II-A . II-B . II-C or II-D in the inflow channel K21 makes in combination with the porous, gas-permeable filter substrate walls FW and the respective inflow and outflow K21, K12 mutually occlusive plug S both carbon monoxide, and unburned hydrocarbons and nitrogen oxides in compliance with the Euro5 standard and Euro6 norm harmless and eliminated also by filtering the particles on the filter substrate walls FW in compliance with the Euro5 standard and Euro6 standard also the particulate matter from the exhaust.

Second embodiment:

According to the in the 3 and 4 illustrated embodiment is now provided that an alternative to use coming two-layer structure II-A . II-B . II-C and II-D is carried out in the inflow channel K21 and an alternative to use single-layered layer structure IA . IB is executed in the outflow K12, according to the second embodiment such that the selected two-layer structure II-A . II-B . II-C and II-D in the inflow channel K21 with the selected single layer layer structure IA . IB does not overlap in the outflow channel K12.

In other words, one of the chosen two-layer coatings II-A . II-B . II-C or II-D is carried out in the inflow channel K21, while the other alternative used single-layered layer structure IA or IB in the outflow channel K12 in the flow direction R seen in the selected two-layered layer structure II-A . II-B . II-C and II-D followed.

According to the 3 and 4 do not overlap the one and two-layer layer structures. They adjoin a so-called imaginary dividing line T, which is formed orthogonal to the flow direction R through the catalyst packet and can be variably fixed locally within the catalyst package.

According to the embodiment of the second embodiment in the 3 and 4 closes the selected single-layered layer structure IA or IB in the illustrated embodiment in the middle M of the catalyst package of the four-way catalyst 400 ' to the selected two-layered layer structure II-A . II-B . II-C or II-D at.

The layer length of the in the 3 and 4 exemplified selected two-layer layer structure II-A . II-B . II-C or II-D is in the second embodiment, 50% of the total channel length of the Anströmkanals K21, wherein the layer length of the subsequent in the flow direction R single-layer structure IA or IB the outflow channel K12 also corresponds to 50% of the total channel length.

This exemplified embodiment has the consequence that the four-way catalyst according to the invention 400 ' due to its share of the chosen two-layer structure II-A . II-B . II-C or II-D in the inlet area of the particle filter 400 ' has improved thermal aging stability, since two-layered layer structures II-A . II-B . II-C or II-D as explained above, are less sensitive to the high thermal load at the same temperature than the single-layered layer structures IA or IB ,

For this reason, the selected two-layered layer structure lies II-A . II-B . II-C or II-D in the flow direction R close to the engine, that is, before the selected single-layered layer structure IA . IB , In other words, the chosen two-layered construction II-A . II-B . II-C or II-D is in an area of the emission control system 200 arranged in the admission tests and in the operation of four-way catalysts 400 ' the highest temperatures, in particular greater than 800 ° C are present.

Each of the two-layer laminates II-A . II-B . II-C or II-D also makes it combined with any single-layered buildup IA or IB as well as the porous, gas-permeable filter substrate walls FW and each of the inflow and outflow K21, K12 mutually closing plug S both carbon monoxide, and unburned hydrocarbons and nitrogen oxides in compliance with the Euro5 standard and Euro6 standard harmless and also eliminates by filtering the particles the filter substrate walls FW also comply with the Euro5 standard and Euro6 standard, the particulate matter from the exhaust.

In this respect, is now through such a configuration according to the second embodiment, another four-way catalyst 400 ' which complies with current and future Euro5 and Euro6 emission standards and known four-way catalytic converters 400 age resistant.

To tune the layer length of the selected two-layer structure II-A . II-B . II-C or II-D and the layer length of the selected single-layered layer structure IA or IB with respect to the respective channel length of the inlet and outlet channel K21, K12 will be discussed below for further different embodiments.

Third embodiment:

According to the third embodiment, it is provided that the selected two-layer structure II-A . II-B . II-C or II-D in the inflow channel K21 and the selected single layer layer structure IA . IB continue to overlap in the outflow channel K12.

However, unlike the second embodiment, the imaginary dividing line T is provided between the selected two-layered layer structure II-A . II-B . II-C and II-D and the selected single-layered layer structure IA or IB starting from the center M of the catalyst package, changing the improved aging effect to the left towards the engine (shortening of the selected two-layer structure II-A . II-B . II-C and II-D less than 50% compared to 4 ) or to the right of the engine (extension of the selected two-layer coating construction II-A . II-B . II-C and II-D greater than 50% compared to 4 ) to move.

In other words, the layer length of the selected two-layer layer structure II-A . II-B . II-C and II-D reduced by shifting the imaginary dividing line T to the left or increased by shifting the dividing line T to the right, while the layer length of the selected single-layer structure IA . IB is increased or reduced accordingly. As a result, the effect is achieved that the mode of action of the aging-resistant two-layer coating structure II-A . II-B . II-C and II-D in an advantageous manner over the layer length within the channel length of the inflow channels K21 of the four-way catalyst 400 ' depending on and observance of the following boundary conditions, namely a raw emission level of the internal combustion engine and / or the exhaust gas standard to be complied with and / or a backpressure behavior at the flow-side beginning of the catalyst package and / or the costs and in particular depending on the temperature occurring or in dependence of a temperature characteristic is variably beinflussbar.

The imaginary dividing line T can thus according to the invention according to the 4 shift to the left or to the right, it being possible in principle that starting from the in 4 shown position of the dividing line T in the middle M of the catalyst packet, a shift of the dividing line T between the selected two-layer layer structure II-A . II-B . II-C and II-D and the selected single-layered layer structure IA . IB of +/- 50% relative to the channel length of the inlet and outlet channels K21, K12 to the left in the direction of the inlet side of the catalyst package or a shift of the dividing line T between the selected two-layered layer structure II-A . II-B . II-C and II-D and the selected single-layered layer structure IA . IB to the right in the direction of exit side of the catalyst package.

It is preferably provided that starting from the in 4 shown position of the imaginary dividing line T in the middle M of the catalyst packet, a shift of the imaginary dividing line T between the selected two-layer layer structure II-A . II-B . II-C and II-D and the selected single-layered layer structure IA . IB of +/- 30% based on the channel length of the inlet and outlet channels K21, K12 to the left in the direction of the inlet side of the catalyst package or a shift of the dividing line T between the selected two-layered layer structure II-A . II-B . II-C and II-D and the selected single-layered layer structure IA . IB to the right in the direction of exit side of the catalyst package.

The imaginary dividing line T between the selected two-layered layer structure II-A . II-B . II-C and II-D and the selected single-layered layer structure IA . IB thus shifts, starting from a 100% channel length of the inlet and outlet channels K21, K12 in the range between 20% and 80%, as for the purpose of illustrating the invention in the 3 and 4 is offered. At least 20% of the channel length of the inflow channel K21 with a selected two-layer layer structure beginning with the inlet side into the catalyst package II-A . II-B . II-C and II-D Mistake. In the range between 0 and 20% of the channel length of the inflow channel K21, the temperatures are in most applications above 800 ° C. By this embodiment in this area is a more resistant aging coating by means of one of the selected two-layer coating structures II-A . II-B . II-C and II-D guaranteed. If the temperatures in other applications beyond the range between 0 and 20% beyond even 800 ° C, the imaginary dividing line T is shifted accordingly to the right, so that the aging resistant coating by means of a selected two-layer structure II-A . II-B . II-C and II-D beginning with the entry side into the catalyst package is also guaranteed in the range between 20% and 80% of the total channel length.

Fourth embodiment:

According to the fourth embodiment, it is provided that the selected two-layer structure II-A . II-B . II-C or II-D in the inflow channel K21 and the selected single layer layer structure IA . IB completely overlap in the outflow channel K12 over the entire channel length of the inlet and outlet channels to 100%. In other words, the inflow channel K21 and the outflow channel K12 are on the entire channel length with the selected two-layered layer structure II-A . II-B . II-C or II-D or the selected single-layered layer structure IA . IB coated.

Preferably, an overlapping zone ÜZ is defined, which serves to illustrate the invention in the 3 and 4 is shown. The overlapping zone ÜZ is starting from the inlet side into the catalyst package between the insides of the respective plugs S of the inflow channels K21 and the outflow channels K12 of the catalyst package of the four-way catalyst 400 ' trained and defined.

As mentioned, it is possible in principle that the selected two-layer structure II-A . II-B . II-C or II-D in the inflow channel K21 and the selected single layer layer structure IA . IB overlap in the outflow channel K12 within the overlap zone ÜZ to 100%.

To save coating material, in particular precious metals, and because of the counter-pressure behavior at the flow-side beginning of the catalyst package and the manufacturing process safety, it is like in 3 and 4 shown preferably provided, only an overlap of the selected two-layer structure II-A . II-B . II-C or II-D in the inflow channel K21 and the selected single layer layer structure IA . IB in the outflow channel K12, based on the overlap zone length of 100%, between a minimum of 20% and a maximum of 80%, taking into account compliance with the abovementioned emission standards.

The overlap of a minimum of 20% to a maximum of 80% within the overlapping zone ÜZ is achieved by the choice of the layer length of the selected two-layer layer structure II-A . II-B . II-C or II-D and / or by the choice of the layer length of the selected single-layer structure IA . IB possible. The overlap has the advantage that layers in the inflow channel K21 and in the outflow channel K12 do not have to adjoin one another sharply, but can overlap to a certain extent.

To increase the thermal aging resistance of the four-way catalyst 400 ' is at a planned overlap of the coating in the inlet and outlet channels K21, K12, the layer length of the selected two-layer structure II-A . II-B . II-C or II-D taking into account the above-mentioned boundary conditions in the inflow channels K21 as long as necessary chosen.

An example:

The chosen two-layered layer structure II-A . II-B . II-C . II-D is carried out, for example, starting from the inlet side to 60% of the total channel length of the inflow channel K21. The single-layered layer structure IA . IB is, for example, as in the 3 and 4 shown executed from the center M to the exit side of the outflow K12. The chosen two-layered layer structure II-A . II-B . II-C . II-D overlaps with the single-layered layer structure IA . IB between 50% and 60% of the possible overlap zone length of 100%.

With respect to the second to fourth embodiments, it is further provided that the alternatively used two-layered layer structures II-A . II-B . II-C or II-D and the alternative used single-layered layer structures IA or IB in accordance with the variants mentioned in the introduction (fourth to twelfth embodiment) in, on or partially in and on the filter substrate wall FW and the filter substrate walls FW of the four-way catalyst 400 ' be coated. As a result, analogously to the first embodiment and the associated variants (first to third embodiment), it is possible in an advantageous manner for producing the four-way catalyst 400 ' All currently known coating methods with their respective advantages can be used.

Arrangement of the catalyst according to the invention 400 in an emission control system 200 :
Depending on the design of the emission control system 200 and the raw emission of the motor vehicle to be cleaned, it may be advantageous, in addition to the four-way catalyst according to the invention 400 ' a three-way catalyst 300 to use. The additional three-way catalyst 300 can upstream or downstream of the four-way catalyst according to the invention 400 ' be arranged.

The 5 shows the arrangement of a motor-related four-way catalyst according to the invention 400 ' behind an internal combustion engine 100 in a first position within an emission control system 200 in front of a three-way catalyst 300 in a second position. The three-way catalyst 300 is within the emission control system 200 remote engine arranged in the underbody of a motor vehicle.

It is preferably proposed, the four-way catalyst according to the invention 400 ' close to the engine and the three-way catalyst 300 downstream of the four-way catalyst 400 to arrange, because the four-way catalyst according to the invention 400 ' as explained in the case of close-coupled arrangement and associated high temperature stress is aging resistant and because at the near-engine higher temperatures better regeneration of the four-way catalyst 400 ' is possible.

An arrangement in a second position (not shown) is possible. Due to lower temperatures is at motor remote arrangement within the emission control system 200 in the second position of the four-way catalyst 400 ' behind a three-way catalyst 300 , the elaborate inventive design of the different layer structure seen in the flow direction R in the inlet and outlet channels K21, K12 not necessarily required.

There is also the possibility (not shown) of the four-way catalyst according to the invention 400 ' in the emission control system 200 alone without a three-way catalyst 300 to arrange. Even then, it requires the desired increase in the thermal aging stability of an embodiment of the four-way catalyst according to the invention 400 ' according to one of the described embodiments and their illustrated embodiments.

Finally, it should be noted that it is due to the design of the invention more thermally aging resistant four-way catalyst 400 ' succeeds, the amounts of the precious metals required for the coatings, starting from the increase in the amounts in the comparison of the known three-way catalysts 300 to the well-known four-way catalysts 400 back to the level of three-way catalysts 300 due. In addition to the increased aging stability, this results in the further advantageous effect of saving precious metals compared with the known four-way catalysts 400 ,

LIST OF REFERENCE NUMBERS

100

internal combustion engine

200

emission control system

300

Three-way catalyst (prior art)

K1

Channel of a three-way catalyst

K2

Channel of a three-way catalyst

W

substrate wall

400

Four-way catalyst (prior art)

400 '

Four-way catalyst (invention)

410

inlet opening

420

outlet opening

430

shell

440

positioning mat

K21

Anströmkanal a four-way catalyst

K12

Outflow channel of a four-way catalyst

FW

Filter substrate wall

T

parting line

M

center

TS

overlap zone

R

Flow direction

1

single-layer coating I

1.

first layer of a two-layer coating II

Second

second layer of a two-layer coating II

I

single-layered layer structure

I-A

first single-layered layer structure

I-B

second single-layered layer structure

II

two-layered layer structure

II-A

first two-layered layer structure

II-B

second two-layer layer structure

II-C

third two-layer layer construction

II-D

fourth two-layered layer structure

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102004040549 A1 [0002, 0006, 0007, 0010]
• EP 2042225 A1 [0003, 0006, 0007, 0008, 0008, 0010]
• EP 2623183 A1 [0004, 0007, 0010]
• DE 602005005022 [0005, 0006]

Claims (12)

Catalytically active particle filter ( 400 ' ) comprising gas-permeable filter substrate walls (FW), which have a filter body with at least one transverse to a flow direction (R) of an exhaust gas through the particulate filter ( 400 ' ) adjacently arranged inlet and outlet channel (K21, K12) form, the inflow channel (K21) downstream and the outflow channel (K12) are closed gas-tight upstream, characterized in that the filter substrate wall (FW) of the inflow channel (K21) at least in an inlet region the exhaust gas into the particulate filter ( 400 ' ) a two-layer catalytic layer structure ( II ; II-A . II-B . II-C . II-D ) with a first catalytic layer ( 1. ) and a second catalytic layer ( Second ) having. Catalytically active particle filter ( 400 ' ) according to claim 1, characterized in that the filter substrate wall (FW) of the inflow channel (K21) in the inlet region of the exhaust gas into the particle filter ( 400 ' ) the two-layer catalytic layer structure ( II ; II-A . II-B . II-C . II-D ) with the first catalytic layer ( 1. ) and the second catalytic layer ( Second ), while the filter substrate wall (FW) of the outflow channel (K12) in an outlet region of the exhaust gas from the particulate filter ( 400 ' ) a single-layer catalytic layer structure ( I ; IA . IB ) with only one catalytic layer ( 1 ) having. Catalytically active particle filter ( 400 ' ) according to claim 1 or 2, characterized in that • the first catalytic layer ( 1. ) of a first two-layer layer structure ( II-A ) Rhodium while the second catalytic layer ( Second ) Palladium or • the first catalytic layer ( 1. ) of a second two-layer layer structure ( II-B ) Contains palladium while the second catalytic layer ( Second ) Rhodium or • the first catalytic layer ( 1. ) of a third two-layer layer structure ( II-C ) Rhodium while the second catalytic layer ( Second ) Contains platinum or • the first catalytic layer ( 1. ) of a fourth two-layer layer structure ( II-C ) Contains platinum while the second catalytic layer ( Second ) Contains rhodium. Catalytically active particle filter ( 400 ' ) according to claim 2,characterized, that •  the catalytic layer ( 1 ) of a first single-layered layer structure ( IA ) Contains palladium and rhodium or The catalytic layer ( 1 ) of a second single-layered layer structure ( IB ) Contains platinum and rhodium. Catalytically active particle filter ( 400 ' ) according to claim 2, characterized in that in the outflow channel (K12) executed single-layer catalytic layer structure ( I ; IA . II-B ) at the in the flow direction (R) seen in the flow channel (K21) running two-layer catalytic layer structure ( II ; II-A . II-B . II-C ; II-D ) without overlapping. Catalytically active particle filter ( 400 ' ) according to claim 2, characterized in that in the inflow channel (K21) executed two-layer catalytic layer structure ( II ; II-A . II-B . II-C ; II-D ) with the single-layer catalytic layer structure (FIG. I ; IA . II-B ) in the flow direction (R) overlaps. Catalytically active particle filter ( 400 ' ) according to claim 1 or 2, characterized in that the layer length of the in-flow channel (K21) running two-layer catalytic layer structure ( II ; II-A . II-B . II-C ; II-D ) in the flow direction (R) as a function of a temperature level along the inflow channel (K21) and / or a raw emission level of an upstream internal combustion engine ( 100 ) and / or at the flow-side end of the particulate filter ( 400 ' ) exhaust gas limits of an exhaust gas standard and / or a backpressure of the particulate filter applied to the flow-side end ( 400 ' ) within an emission control system ( 200 ) varies. Catalytically active particle filter ( 400 ' ) according to claim 1 or 2, characterized in that the two-layered catalytic layer structure ( II ; II-A . II-B . II-C . II-D ) is formed in the inflow channel (K21) as a function of the temperature level along the inflow channel (K21) only in a region near the engine of the inflow channel (K21) in which a temperature greater than 800 ° C. prevails. Catalytically active particle filter ( 400 ' ) according to claim 6, characterized in that in the inflow channel (K21) executed two-layer catalytic layer structure ( II ; II-A . II-B . II-C ; II-D ) with the single-layer catalytic layer structure (FIG. I ; IA . II-B ) in the flow direction (R) seen within a between the downstream end of the Anströmkanals (K21) and the At the upstream end of the outflow channel (K12) formed overlap zone (ÜZ) of the particulate filter ( 400 ' ) partially or completely overlapped. Catalytically active particle filter ( 400 ' ) according to claim 1 or 2, characterized in that the layers ( 1. . Second ) of the two-layer catalytic layer structure ( II ; II-A . II-B . II-C . II-D ) and / or the layer ( 1 ) of the single-layer catalytic layer structure ( I ; IA . IB ) optionally • on the filter substrate wall (FW) or • in the filter substrate wall (FW) or • partially in and on the filter substrate wall (FW) is / are formed. Emission control system ( 200 ) for cleaning the exhaust gases of a predominantly stoichiometrically operated internal combustion engine ( 100 ) comprising a catalytically active particulate filter ( 400 ' ) according to at least one of claims 1 to 10. Emission control system ( 200 ) according to claim 11, characterized in that the catalytically active particulate filter ( 400 ' ) is arranged in the motor-near position.

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