DE4207005A1 - Exhaust gas cleaner for vehicle combustion engine - has parallel arrangement of catalytic converter filter - Google Patents

Abstract

Exhaust gas cleaner for a combustion engine having a exhaust piep (2, 3) containing a filter element (8) to trap particles in the exhaust gas as the exhaust gas flows through the exhaust piep, and a catalytic converter (9) which has a honeycomb shaped catalyst carrier. The filter element and the catalystic converter are set parallel to the flow of the exhaust gas and at least one throttle opening (10) is fitted in series with the catalystic converter. ADVANTAGE - Exhaust gas cleaner in which the collection of particles in the filter element is suppressed to such an extent that burn out of the filter element is prevented.

Description

The invention relates to an exhaust gas cleaner for internal combustion engines, in particular especially for diesel engines, according to the preamble of the main claim.

It is known to use exhaust gas purifiers for trapping exhaust gas particles such as e.g. B. Koh lenstoff and other substances, the soluble organic fragments or Frak are to be installed in the exhaust system of internal combustion engines.

Japanese Patent Publication 56-1 24 417 (U.S. Patent 43 64 761) discloses an exhaust gas purifier with a monolithic ceramic filter element that has porous inner walls, the parallel, alternating next to form mutually arranged inlet and outlet channels. The channels include Inlet channels that are open on one side of the filter element and on the other ren side of the filter element are closed, and outlet channels, the reverse returns open and closed.

Japanese Patent Publication 62-45309 (U.S. Patent No. 4,732,594) discloses another type of exhaust gas cleaner with a filter element made of porous ceramic material, in particular from known ceramic foam.

As soon as the amount of exhaust gas particles trapped in the filter element is a pre has reached the specified level, the exhaust gas particles with a Bren ner or burned by the heat of the exhaust gas, so that the filter element regenerates becomes. However, if the engine is under for a long time Operating at low speed conditions is the exhaust temperature not high enough to burn the captured exhaust particles. As a result, a large amount of exhaust gas particles are caught in the filter element collects. The moment of the low-speed conditions switched to high speed and high load conditions becomes, the filter element tends to heat up and due to the excessive Heat production due to the combustion of the large amount in the fil burn out the accumulated exhaust particles.

European patent 03 80 065 discloses an exhaust gas cleaner that a filter element and a catalytic converter with a honeycomb contains catalyst supports, which are arranged in an exhaust pipe.

It is an object of the invention to collect exhaust particles in an egg Suppress nem filter element of an exhaust gas filter so far that the off burning of the filter element can be prevented.

This object is achieved by an exhaust gas cleaner for Internal combustion engines, with a filter element installed in an exhaust pipe element for trapping particles flowing in through the exhaust pipe Exhaust gas are carried along, and with a catalytic arranged in the exhaust pipe Converter, which has a honeycomb-shaped catalyst carrier, because characterized in that the filter element and the catalytic conversion ler are arranged in parallel with respect to the flow direction of the exhaust gas, and that at least one throttle opening in series with the catalytic Um converter is arranged.

Preferred exemplary embodiments of the invention are described below the accompanying drawing explained.

Fig. 1 shows a longitudinal section through an inventive gas cleaner;

FIG. 2 is a cross section through the exhaust gas purifier from FIG. 1 along the line AA;

Fig. 3 shows the outline of a throttle opening plate used in the exhaust gas purifier according to the invention;

Fig. 4 is a diagram showing a characteristic of trapping exhaust gas particles in a filter element of a gas cleaner from the present invention;

Fig. 5 is a graph showing a characteristic of the flow rate of exhaust gas flowing through a catalytic converter of an exhaust gas purifier according to the invention;

Fig. 6 is a graph showing a characteristic of the removal rate of accumulated exhaust particles;

Fig. 7 shows the schematic of a further embodiment of an inventive exhaust gas cleaner.

As shown in FIG. 1, an exhaust gas cleaner comprises a housing 1 with a cylindricity's outer wall 1 and a funnel-shaped upstream and downstream end portions 1 b and 1 c. The upstream end piece 1 b forms an inlet 101 and is connected via an upstream part 2 of an exhaust pipe to an exhaust system, not shown. The downstream end piece 1 c forms an outlet 103 and is connected to a downstream part 3 of the exhaust pipe. The upstream end piece 1 b can either be integrally formed with the cylindrical outer wall 1 a or separately therefrom. The downstream be sensitive tail 1 c is provided at its upstream end with egg nem flange 1 d through which it is connected to the downstream end of the cylindrical outer wall 1 a.

The housing 1 has a cylindrical inner wall 5 which is connected to the cylindrical outer wall 1 a, so that a double-walled structure is formed. The upstream end of the inner wall 5 is flush with that of the cylindrical outer wall 1 a, and the downstream end protrudes by a predetermined distance beyond the downstream end of the cylindrical outer wall 1 a in the direction of the outlet 103 . If the cylindrical outer wall 1 a and the downstream end piece 1 c are assembled to the housing 1 , the cylindrical inner wall 5 forms a cylindrical through hole 6 , while between the cylindrical outer wall 5 and the cylindrical inner wall 1 a an annular space 7 is formed.

In Fig. 2 it can be seen that a cylindrical filter element 8 is arranged in the cylindrical through hole 6 . The filter element 8 is in the longitudinal direction as long as the cylindrical outer wall 1 a, and its mutually opposite end faces are facing the inlet 101 and the outlet 103 . The filter element 8 consists of a porous material such as. B. po röser ceramic, ceramic foam, wire mesh or the like. The Filtere element 8 catches exhaust particles such. B. carbon.

In the annular space 7 , an annular catalytic converter 9 is accommodated, which is as long as the cylindrical outer wall 1 a in the longitudinal direction, and the opposite end faces of the inlet 101 and the outlet 103 are facing. The catalytic converter 9 comprises a honeycomb, provided with a metal catalyst catalyst support such. B. a metallic honeycomb structure, which is produced by ringför shaped rolling up of a layer plate of alternately superimposed flat and corrugated metal sheets. The catalytic converter 9 mainly captures soluble organic fragments. A monolithic ceramic material having a honeycomb structure can also be used in the catalytic converter 9 .

As described above, the filter element 8 and the catalytic converter 9 extend over the entire length of the cylindrical outer wall 1 a, so that their upstream and downstream end faces are each in one plane.

An annular throttle opening plate 4 forms a downstream end of the annular space 7 and is held firmly in an annular recess which is formed on the inside of the funnel-shaped downstream end piece 1 c attached flange 1 d.

The throttle opening plate 4 has a central opening with the same diameter as the inner diameter of the inner wall 5th Is fixed when the piece 1 downstream c as on the outer cylindrical wall 1 a in that the end of the inner wall 5 downstream abuts an inner edge of the upstream face of the orifice plate 4, the central opening of the orifice plate 4 is flush with the through the main through hole 6 formed in the inner wall 5 . In addition, since the downstream end of the inner wall 5 protrudes beyond the in-plane lying end faces of the filter element 8 and the catalytic converter 9 , between the upstream end face of the throttle opening plate 4 and the downstream end faces of the filter element and the catalytic converter 9 formed an axial gap. The throttle opening plate 4 has a plurality of throttle openings 10 , which are net angeord at equal angular intervals, as shown in FIG. 3.

In the vicinity of the inlet 101 , a fuel injection system (not shown) can be attached, which supplies fuel to support the combustion of exhaust gas particles collected in the filter element 8 .

In operation, exhaust gas discharged from the internal combustion engine leads through the upstream part 2 of the exhaust system into the exhaust gas purifier. The exhaust gas flows in separate gas flows through the filter element 8 and the catalytic converter 9 . Flow resistances arise through the filter element 8 , the catalytic converter 9 and the throttle opening plate 4 . Because of the structural differences between the filter element 8 and the catalytic converter 9, the flow resistance of the ka talytischen converter 9 is lower than that of the filter element. 8 The flow resistance of the catalytic converter 9 is controlled by the throttle opening plate 4 . As a result, the flow ratio can be kept in a certain range. So z. B. in an initial stage of exhaust gas emission, the flow ratio is set to approximately 50% of who.

The total area of the throttle openings 10 is determined so that the amount of the exhaust gas particles accumulated in the filter element 8 remains below a critical value. The critical value is the burn-out value at which a burn-out of the filter element 8 is caused by the sudden temperature rise of the exhaust gases, which occurs when the accumulated exhaust gas particles are burned.

As can be seen from the diagrams of FIGS. 4 and 5, the amount of the exhaust gas particles accumulated in the filter element 8 varies within a certain range when the internal combustion engine is operated under normal driving conditions, in which normal accelerations and decelerations are repeated. The amount of exhaust gas particles collected in the filter element 8 gradually increases. When accelerated, the exhaust gas particles accumulated in the filter element 8 are burned due to the temperature increases in the exhaust gas, so that the filter element is regenerated. As a result, the accumulation of exhaust gas particles in the filter element 8 is restricted to a relatively low value.

When the internal combustion engine is operated for a long period of time under low-speed conditions, the amount of the exhaust gas particles accumulated in the filter element 8 gradually increases. As a result, the flow resistance in the filter element 8 increases , so that the throughput of exhaust gas through the filter element 8 decreases, while the throughput of exhaust gas through the catalytic converter 9 increases. If the amount of the exhaust gas particles accumulated in the filter element 8 continues to increase to the burnout value, the majority of the exhaust gas can bypass the filter element 8 . Thus, the further accumulation of exhaust gas particles in the filter element 8 is suppressed, so that the filter element 8 is prevented from burning out until it can regenerate again after changing to high-speed conditions. In addition, even if the majority of the exhaust gas flows through the catalytic converter 9 , the removal rate of exhaust gas particles by trapping and removing soluble organic fragments is kept at a certain value, as the diagram in FIG. 6 shows.

In addition, the arrangement of the filter element 8 surrounding the catalytic converter 9 allows the filter element 8 to be protected from heat loss, even if the majority of the exhaust gas flows through the catalytic converter 9 . As a result, the filter element 8 is quickly regenerated when changing to high-speed conditions.

According to FIG. 7 in another embodiment, a erfindungsge rectly exhaust filter comprises two cylindrical housings 12 and 14 in which a filter element 11 of porous material such. B. ceramic foam and a catalytic converter 13 , which has a honeycomb-shaped catalyst carrier with a catalyst, are housed. The housing 12 defines a main flow channel 18 and is connected at its upstream end to an inlet pipe 15 and at its downstream end to an outlet pipe 16 . On the other hand, the housing 14 defines a bypass duct 19 and is also connected to the inlet and outlet pipes 15 and 16 at its upstream and downstream ends via bypass pipes 17 . The housing 14 is thus arranged parallel to the housing 12 . The bypass pipe 17 connected to the downstream side of the housing 14 is provided with a throttle opening 20 .

As the arrows in FIG. 7 show, the exhaust gas flowing through the inlet pipe 15 is distributed to the main and secondary flow channels 18 and 19 , flows through the filter element 11 and the catalytic converter 13 and is combined in the outlet pipe 16 .

Similarly as in the first embodiment, the amount of the Filterele ment 11 accumulated exhaust particulates characterized below a burnout level at which the burn-out of the filter element 11 occurs, maintained that in dependence on the Ausbrennwert the opening area of the throttle opening is set appropriately 20th

Claims (4)

1. Exhaust gas cleaner for internal combustion engines, with a filter element ( 8 , 11 ) arranged in an exhaust pipe ( 2 , 3 ) for trapping particles in exhaust gas flowing through the exhaust pipe, and with a catalytic converter ( 9 , arranged in the exhaust pipe ( 2 , 3 ) 13 ), which has a honeycomb-shaped catalyst carrier, characterized in that the filter element ( 8 , 11 ) and the catalytic converter ( 9 , 13 ) are arranged parallel to the flow direction of the exhaust gas, and in that at least one throttle opening ( 10 , 20th ) is arranged in series with the catalytic converter ( 9 , 13 ). 2. Exhaust gas purifier according to claim 1, characterized in that the catalytic converter ( 9 ) has a cylindrical through opening ( 6 ) in which the filter element ( 8 ) is arranged. 3. Exhaust gas cleaner according to claim 2, characterized in that the exhaust gas cleaner has a double wall structure ( 1 a, 5 ) which comprises a cylindrical outer wall ( 1 a) and a cylindrical inner wall ( 5 ) defining the cylindrical through opening ( 6 ), that the catalytic converter ( 9 ) egg nen between the cylindrical inner wall ( 5 ) and the cylindrical outer wall ( 1 a) located, annular space ( 7 ) fills, and that we least one throttle opening ( 10 ) in an annular, an axial end of the annular space ( 7 ) forming throttle opening plate ( 4 ) is formed out. 4. Exhaust gas purifier according to claim 1, characterized in that the catalytic converter ( 13 ) in a filter element ( 11 ) bypassing secondary flow channel ( 17 ) is arranged, and that the throttle opening ( 20 ) downstream of the catalytic converter ( 13 ) in Secondary flow channel ( 17 ) is attached.