EP1574680A1 - Exhaust gas purification system for the combustion engine of an automotive vehicle and exhaust line comprising such a system - Google Patents

Abstract

Automobile engine exhaust gas purification system comprises inlet channels with a open front end and a closed rear end, outlet channels with a closed front end and a open rear end, an oxidation catalyst at the front end of the inlet channels, and a catalyst-regenerating plasma discharge system at the rear end of the inlet channels. Automobile engine exhaust gas purification system comprises inlet channels (1) with a open front end and a closed rear end, outlet channels (2) with a closed front end and a open rear end, an oxidation catalyst (5a) comprising a layer of catalyst-impregnated material at the front end of the inlet channels, and a catalyst-regenerating plasma discharge system comprising electrodes (6, 7) that are embedded in a dielectric barrier (5b) at the rear end of the inlet channels and are connected to an electricity supply. An independent claim is also included for an automobile exhaust train comprising a system as above.

Description

The present invention relates to a gas purification system exhaust system of a motor vehicle engine and a line exhaust system comprising such a system.

More particularly, the invention relates to such a system, of the type comprising a gas purifying member disposed in a line exhaust system associated with the engine and having gas inlet channels to purify, having an open front end and a closed rear end, and purified gas outlet channels having a closed front end and an open back end.

Pollutants resulting from the combustion of a diesel or gasoline engine are mainly unburnt hydrocarbons, nitrogen oxides (monoxide Nitrogen Nitrogen and Nitrogen Dioxide NO2), carbon oxides (carbon monoxide CO and carbon dioxide CO2) and, in the case of diesel engines and gasoline direct injection engines, particles.

In order to comply with international environmental standards, control of HC, CO, NOx and particulate emissions, is imperative and post-processing technologies are essential.

Different technological solutions have been developed and evaluated to reduce the pollution levels of internal combustion engines.

The treatment of particles from diesel engines is possible thanks to the introduction into the exhaust line of these engines a filter to particles for example. These filters are designed to trap soot particles contained in the exhaust gases during their flow in the line exhaust and require a combustion phase to prevent fouling damaging to the engine and the vehicle.

a) L'ajout d'un composé préférentiellement de type organométallique dans le carburant pour permettre de réduire la température de combustion des particules et de favoriser la propagation du phénomène de combustion dans le lit de suie de par la présence de cet additif dans la structure de chaque particule formée dans la chambre de combustion. Pour adapter ce concept aux conditions de températures rencontrées sur les moteurs fonctionnant en mélange pauvre, notamment sur les moteurs Diesel, l'additivation du carburant doit être couplée à une stratégie de post-injection de carburant dans les cylindres pour créer un exotherme en amont du filtre grâce à l'ajout d'un catalyseur d'oxydation. Les principales difficultés rencontrées par cette stratégie sont liées à la production de cendres, du fait de la présence d'un additif organométallique dans la structure des suies et des additifs présents dans l'huile de lubrification du moteur, conduisant à une maintenance régulière et à une surconsommation en carburant du fait de la post-injection pour atteindre les conditions thermiques de combustion des particules de suie.

b) L'imprégnation des parois du filtre à particules avec un catalyseur d'oxydation permettant d'abaisser la température de combustion des suies et d'assurer un nettoyage des parois du filtre en continu. Les problèmes mis en évidence avec ce concept sont une régénération partielle du filtre du fait de la difficulté à propager le phénomène de combustion au sein du lit de suies et la nécessité d'une stratégie de chauffage des gaz pour éviter d'atteindre la masse limite en suies dommageable pour le système filtrant et le moteur.

c) Le chauffage électrique du média filtrant par introduction de résistances électriques dans les filtres. Cette technologie est assez peu développée, essentiellement en raison du fait de la consommation électrique et donc de la surconsommation en carburant.

Different regeneration strategies have already been considered, such as:

a) The addition of a compound of organometallic type in the fuel to reduce the combustion temperature of the particles and to promote the propagation of the combustion phenomenon in the soot bed by the presence of this additive in the structure of each particle formed in the combustion chamber. To adapt this concept to the temperature conditions encountered on engines operating in lean mixture, especially on diesel engines, the fuel additive must be coupled with a strategy of post-injection of fuel into the cylinders to create an exotherm upstream of the engine. filter thanks to the addition of an oxidation catalyst. The main difficulties encountered by this strategy are related to the production of ash, due to the presence of an organometallic additive in the soot structure and additives present in the engine lubricating oil, leading to regular maintenance and overconsumption of fuel due to post-injection to achieve the thermal combustion conditions of the soot particles.

b) The impregnation of the walls of the particulate filter with an oxidation catalyst to lower the soot combustion temperature and ensure cleaning of the walls of the filter continuously. The problems highlighted with this concept are a partial regeneration of the filter because of the difficulty to propagate the combustion phenomenon within the soot bed and the need for a gas heating strategy to avoid reaching the mass limit. in soot damaging to the filter system and the engine.

c) Electric heating of the filter media by introducing electrical resistances into the filters. This technology is not very developed, mainly because of the fact of the electric consumption and thus of the overconsumption in fuel.

a) La production de décharges plasma en amont d'un filtre à particules pour produire du NO2 et favoriser la réaction d'oxydation des suies par le NO2 produit par le plasma. Cette technologie se rapproche du concept connu sous le nom de CRT (Continuous Regeneration Technology) en substituant le catalyseur d'oxydation en amont du filtre par un réacteur à ionisation des gaz. La difficulté majeure réside dans la capacité de ce concept à assurer la régénération passive du filtre sur la plage de températures rencontrée sur les applications sur véhicules particuliers à moteur Diesel.

b) La production de décharges plasma directement dans le filtre à particules en localisant les électrodes dans les canaux de sortie des gaz d'échappement. Dans ce concept, le champ créé par les décharges plasma est généré dans un espace exempt de suies et une étape de propagation à travers les parois du filtre est nécessaire afin de générer des phénomènes de combustion des particules.

c) Un dernier concept propose d'induire les décharges directement dans les canaux remplis de suies entre des anodes constituées de fils placés longitudinalement dans les canaux d'entrée du filtre et des cathodes constituées d'une plaque agencée dans au moins un plan sensiblement horizontal à l'extérieur du bloc de traitement. Cependant, ce concept est très délicat à réaliser de par le nombre important d'électrodes à insérer dans le média filtrant et les systèmes de fixation des électrodes, placés en entrée du filtre, engendrent des réductions de capacité de stockage et des pertes de charge importantes pour des systèmes déjà très pénalisants pour des applications sur véhicules.

An alternative for performing this soot combustion step is to use plasma discharges to oxidize the particles. Several approaches have already been presented, including:

a) The production of plasma discharges upstream of a particulate filter to produce NO2 and to promote the soot oxidation reaction by the NO2 produced by the plasma. This technology is close to the concept known as CRT (Continuous Regeneration Technology) by substituting the oxidation catalyst upstream of the filter by a gas ionization reactor. The major difficulty lies in the ability of this concept to ensure the passive regeneration of the filter over the temperature range encountered on applications on passenger cars diesel engine.

b) The production of plasma discharges directly into the particulate filter by locating the electrodes in the exhaust gas outlet channels. In this concept, the field created by the plasma discharges is generated in a space free of soot and a step of propagation through the walls of the filter is necessary in order to generate phenomena of combustion of the particles.

c) A last concept proposes to induce the discharges directly in the channels filled with soot between anodes consisting of son placed longitudinally in the inlet channels of the filter and cathodes constituted by a plate arranged in at least one substantially horizontal plane outside the treatment block. However, this concept is very difficult to achieve due to the large number of electrodes to be inserted in the filter medium and the electrode fixing systems placed at the inlet of the filter, generate reductions in storage capacity and significant pressure drops. for systems already very penalizing for applications on vehicles.

For example, reference may be made to documents FR-A-2 830 566 and FR-A-2,830,275.

The object of the invention is therefore to solve these problems.

For this purpose, the subject of the invention is a gas purification system of a motor vehicle engine, of the type comprising a gas purification unit disposed in an exhaust line associated with the engine and having gas inlet channels to be purified, having an open front end and a closed rear end, and channels purified gas outlet having a closed front end and an end backward, and associated with oxidation catalyst means and plasma discharge generator means for regeneration assistance of the purification unit, characterized in that the catalyst means are in the form of a layer of catalytic impregnating material, deposited on the open front end side of the inlet channels, and the means forming a plasma discharge generator are in the form of electrodes disposed on the closed rear end side of these channels input, embedded in a layer of dielectric barrier material and connected to a source of electrical power supply.

• les électrodes des moyens formant générateur de décharges plasma et la couche de matériau formant barrière diélectrique s'étendent le long des canaux d'entrée sur au moins un tiers de la longueur de ceux-ci et la couche de revêtement catalytique s'étend sur le reste de la longueur de ces canaux ;
• les électrodes sont adaptées pour traverser l'extrémité obturée du canal d'entrée ;
• les électrodes sont formées d'au moins une cathode et une anode dans chaque canal d'entrée ;
• l'organe de purification comporte plusieurs rangées empilées de canaux d'entrée et de sortie successifs et de section carrée, et les électrodes des canaux d'entrée, sont placées dans des coins opposés de chaque canal d'entrée, respectivement, en haut ou en bas, et à gauche ou à droite du canal, de manière que les électrodes correspondantes de deux rangées empilées, soient les plus proches les unes des autres ;
• l'organe de purification est un filtre à particules ;
• les canaux de sortie sont revêtus sur toute leur longueur d'une couche d'imprégnation catalytique ;
• le matériau formant barrière diélectrique est formé d'un matériau d'imprégnation catalytique sans métaux ; et
• l'épaisseur de la couche de matériau formant barrière diélectrique est inférieure ou égale à celle de la couche de matériau catalytique.

According to other characteristics:

• the electrodes of the plasma discharge generator means and the layer of dielectric barrier material extend along the inlet channels for at least one third of the length thereof and the catalytic coating layer extends over the remainder of the length of these channels;
• the electrodes are adapted to pass through the closed end of the inlet channel;
• the electrodes are formed of at least one cathode and an anode in each input channel;
• the purification unit comprises several stacked rows of successive input and output channels of square section, and the electrodes of the input channels, are placed in opposite corners of each input channel, respectively, at the top or bottom, and left or right of the channel, so that the corresponding electrodes of two rows stacked, are closest to each other;
• the purification member is a particulate filter;
• the outlet channels are coated throughout their length with a catalytic impregnation layer;
• the dielectric barrier material is formed of a metal-free catalytic impregnating material; and
• the thickness of the dielectric barrier material layer is less than or equal to that of the catalytic material layer.

According to another aspect, the invention also relates to a line exhaust system comprising such a system.

The present invention therefore proposes to focus on the phenomena soot storage and distribution of the soot in the filter so to optimize the last concept presented previously. Indeed, the gas flows imposed by the operation of the engine lead to a distribution of the soot bed quite fine on the upstream part of the filter inlet channels and a bed of soot that thickens as the gas flow evolves towards the bottom of the canals. After several hours of engine operation, the vast majority soot forms a compact bed in the bottom of the channels.

Under these conditions, any system that can oxidize the soot bed compact located in the bottom of the inlet channels of the filter leads to regeneration compatible with the constraints of a vehicle application. The solution proposed by this invention is a plasma concept for performing this step. To complete the combustion phenomenon and propose a system with a regeneration efficiency close to the strategy with an additive filter, support catalytic is impregnated on the upstream part of the corresponding input channels to the formation area a finer soot bed. It is recognized that the difficulty encountered in the case of catalysed filters is the spread of combustion through the bed of soot. In the context of the invention, the catalytic support is located in a favorable area for the oxidation of soot. The coupling of these two approaches leads to a compact invention to achieve regeneration total soot accumulated in a particulate filter.

The present invention therefore consists in proposing an architecture of plasma reactor for treating the bed of particles accumulated in the channels of a filter by proceeding catalytically on the front part of the channels input when the soot bed is thin and regenerating via plasma discharges the bottom part of these same input channels when the soot bed becomes compact and thick.

The principle of plasma is to generate metastable species, radicals and very reactive ions by collision between the constituent molecules the exhaust gases and the energy electrons produced by landfills electric, and this without raising the temperature of the reaction medium.

The physical characteristics of electric shocks vary according to the intended application, consumptions and conversion levels needed for engine applications including motor vehicles (variable frequency, voltage and intensity).

Metastable species, radicals and highly energetic electrons products are promoters of chemical oxidation in a gas exhaust containing an excess of oxygen, such as particles of soot, by direct interaction of these species with very short lifespans with pollutants.

The catalytic support makes it possible to ensure the oxidation of the particles of soot through activated oxidation reactions via metals, in particular precious metals dispersed in a catalytic material itself impregnated on the walls of the filter. This system can be considered in the precise case of this concept because the soot bed deposited on the catalytic support is end on the input part of the filter and therefore the propagation of the combustion does not will not be a limiting parameter as was found in the case of particles catalyzed.

a) Les canaux d'entrée d'un filtre à particules nu sont imprégnés d'une formulation catalytique oxydante permettant la combustion des suies. La zone d'imprégnation est au maximum des deux tiers de la longueur totale du filtre considéré. La longueur totale du filtre dépend de la cylindrée du moteur et de l'espacement envisagé entre deux régénérations dans le cas d'un concept séquentiel. La contre-pression engendrée par le filtre est également un critère important.

b) La zone de décharges plasma est au moins de un tiers de la longueur totale du filtre. Dans cette zone, au moins deux électrodes diamétralement opposées sont introduites dans le filtre par introduction de ces électrodes au travers du ciment bouchant les extrémités arrières des canaux d'entrée du filtre. Ces électrodes sont noyées dans une couche de matériau formant barrière diélectrique. Ceci permet de maintenir les électrodes en place sur la partie arrière du filtre. De plus, l'utilisation d'une telle barrière diélectrique recouvrant ces électrodes générant les décharges plasma, permet une dispersion des espèces activées par le plasma, à savoir les ions fortement énergétiques, à la surface de ce diélectrique, avant d'atteindre les conditions de seuil de claquage. La conséquence est un risque de passage à l'arc électrique destructif pour le média filtrant plus faible à iso-énergie injectée dans la zone plasma que lorsqu'il n'y a pas de barrière diélectrique.De plus, la distribution des charges est également plus homogène à la surface de la barrière diélectrique, augmentant par la même, le potentiel de formation d'une zone inter-électrode plus homogène dans le sens de l'écoulement, comparativement à un système d'électrodes non recouverte d'une barrière diélectrique.On sait en effet que ce type de configurations présente l'inconvénient de favoriser la création d'un milieu plasmagène fortement hétérogène dans le sens de l'écoulement des gaz et radialement par rapport à ce même écoulement.Or, cette hétérogénéité est fortement défavorable pour l'efficacité de conversion des polluants, et particulièrement des suies accumulées en lit dans le filtre à particules. En fait, le matériau formant barrière diélectrique peut être formé d'un matériau d'imprégnation catalytique sans métaux.Ceci permet d'éviter le passage à l'arc des décharges, la partie catalytique étant positionnée en face avant des canaux d'entrée du filtre, pour traiter le lit de suies le plus fin.Cette imprégnation catalytique peut alors contenir des métaux, préférentiellement des métaux précieux.On notera également que l'épaisseur de la couche d'imprégnation peut être différente sur la partie avant et sur la partie arrière des canaux. Dans ce cas, la couche de matériau formant barrière diélectrique présente de préférence, une épaisseur inférieure ou égale à celle de la couche de matériau catalytique afin de réduire au maximum l'épaisseur de la barrière diélectrique.

c) Chaque canal d'entrée du filtre est équipé d'au moins deux électrodes et d'un support catalytique pour assurer un traitement de tous les canaux contenant des particules de suie.

d) Dans chaque canal, au moins l'une des deux électrodes correspond à une anode et l'autre à une cathode, respectivement connectées à la haute tension électrique et à la masse.

e) Dans le cas du filtre complet, si une anode est positionnée dans la partie supérieure d'une rangée de canaux d'entrée du filtre, la rangée directement située au-dessus présente l'électrode d'anode correspondante située dans la partie inférieure du canal. Cela permet d'avoir des connexions uniques par rangée localisées à l'arrière du filtre.

The preferred configuration of this architecture of the soot particle treatment reactor is described as follows:

a) The inlet channels of a naked particle filter are impregnated with an oxidizing catalytic formulation allowing the combustion of soot. The impregnation zone is at most two thirds of the total length of the filter considered. The total length of the filter depends on the displacement of the engine and the spacing envisaged between two regenerations in the case of a sequential concept. The back pressure generated by the filter is also an important criterion.

(b) The plasma discharge zone is at least one third of the total length of the filter. In this zone, at least two diametrically opposite electrodes are introduced into the filter by introducing these electrodes through the cement plugging the rear ends of the filter inlet channels. These electrodes are embedded in a layer of dielectric barrier material. This keeps the electrodes in place on the back of the filter. In addition, the use of such a dielectric barrier covering these electrodes generating the plasma discharges, allows a dispersion of the species activated by the plasma, namely the highly energetic ions, on the surface of this dielectric, before reaching the conditions threshold of breakdown. The consequence is a risk of destructive electric arc switching for the lower iso-energy filter media injected into the plasma zone than when there is no dielectric barrier. Moreover, the distribution of the charges is also more homogeneous at the surface of the dielectric barrier, thereby increasing the potential for forming a more homogeneous inter-electrode region in the direction of flow, compared to an electrode system not covered by a dielectric barrier Indeed, it is known that this type of configuration has the disadvantage of favoring the creation of a highly heterogeneous plasmagenic medium in the direction of gas flow and radially with respect to this same flow. Or, this heterogeneity is strongly unfavorable. for the efficiency of conversion of pollutants, and particularly soot accumulated in bed in the particulate filter. In fact, the dielectric barrier material may be formed of a catalytic impregnation material without metals. This makes it possible to avoid the arc transition of the discharges, the catalytic part being positioned on the front face of the inlet channels of the filter, to treat the finest soot bed.This catalytic impregnation can then contain metals, preferably precious metals.It will also be noted that the thickness of the impregnation layer may be different on the front part and on the part back of the channels. In this case, the layer of dielectric barrier material preferably has a thickness less than or equal to that of the catalytic material layer to minimize the thickness of the dielectric barrier.

c) Each inlet channel of the filter is equipped with at least two electrodes and a catalytic support to ensure treatment of all channels containing soot particles.

d) In each channel, at least one of the two electrodes corresponds to an anode and the other to a cathode respectively connected to the high voltage and to the ground.

e) In the case of the complete filter, if an anode is positioned in the upper part of a row of filter inlet channels, the row directly above it has the corresponding anode electrode located in the lower part of the canal. This allows for single connections per row located at the back of the filter.

• la Fig.1 représente une vue en coupe longitudinale d'un canal d'entrée et d'un canal de sortie d'un système de purification selon l'invention ; et
• la Fig.2 représente une vue de face d'un tel système de purification.

The invention will be better understood on reading the description which follows, given solely by way of example and with reference to the appended drawings, in which:

• Fig.1 shows a longitudinal sectional view of an inlet channel and an outlet channel of a purification system according to the invention; and
• Fig.2 shows a front view of such a purification system.

As mentioned above, the invention relates to to a system for purifying the exhaust gases of a combustion engine motor vehicle.

This system comprises a gas purification unit disposed in an exhaust line associated with the engine and having channels the gases to be purified and the outlet channels of the purified gases.

For example, in FIG. 1, an input channel of FIGS. gas to be purified by general reference 1, and a gas outlet channel purified, designated by general reference 2.

In fact, the purification unit comprises such channels arranged in rows and columns of successive input and output channels.

Each input channel designated by general reference 1 presents an open front end and a closed rear end, for example, to using a cement plug designated by the general reference 3.

In contrast, each output channel has one end before closed for example by a cement plug, designated by the reference 4 and an open rear end.

In such a concept, the exhaust gases are therefore circulated between the input channels and the output channels, through the filter media which is then required to trap the particles contained in these gases.

As previously stated, such an organ needs to be regenerated regularly to ensure combustion of trapped particles.

For this purpose, one can associate with this type of organs, means forming oxidation catalyst and plasma discharge generator means.

In the purification system according to the invention, the means forming catalyst are in the form of a layer of impregnating material catalytic converter, deposited on the side of the open front end of the inlet channels, this layer being designated for example by the general reference 5a.

In addition, the means forming a plasma discharge generator are presented in the form of electrodes designated by general references 6 and 7 in this figure, which are arranged on the closed rear end side of these inlet channels and are embedded in a layer of barrier material 5b, and connected to a source of electrical power supply boarded the vehicle.

In fact, one of these electrodes may correspond to an anode connected to the high voltage terminal of the source, while the other electrode can match to a cathode connected for example to ground.

It is then conceivable that the electrodes of the generator means of plasma discharges and the layer of dielectric barrier material extend along the inlet channels of the purification member, and this on less than a third of the length of these.

The catalytic impregnation can then extend over a maximum of two third of the length of the canal.

In the exemplary embodiment shown, the electrodes are adapted to pass through the closure means 3 of the corresponding rear end of the inlet channel, and to extend towards the layer of material forming dielectric barrier 5b.

These electrodes are then embedded in this layer of material 5b, to keep them in position.

This makes it possible to guarantee that these electrodes are held in position in the channels.

The dielectric barrier material 5b may be formed of a material catalytic impregnation without metals.

A zone deposition technique of this material can then be used to deposit these layers on the channels.

Also preferably, the thickness of the layer of material forming dielectric barrier is less than or equal to that of the layer of material Catalytic.

This layer of catalytic material may then comprise metals, such as for example precious metals.

It is conceivable then that each input channel can be equipped with such electrodes as shown in Figure 2.

In the case for example where the channels have a square section, the electrodes, i.e. cathode and anode, are arranged in opposite corners of these.

Preferably, the corresponding electrodes of the channels of the rows stacked on top of each other, are placed respectively in the upper or lower corners, and left or right, so that the electrodes two rows of stacked rows are the closest to each other. others, to facilitate their connection to the power supply

For example, if we consider rows 8, 9 and 10 channels, illustrated in this figure 2, it can be seen that the cathodes, by example 11, channels of row 8, are placed in the bottom left corner of these, and that the corresponding cathodes, for example 12, channels of row 9, are placed in the upper left corner thereof, so to facilitate their connection.

Similarly, the anodes, for example 13 of the row 9 of channels, are placed in the lower right corner of these, while the anodes, for example 14, of the row of channels 10, are placed in the upper right corner of these, which also facilitates their connection.

It is conceivable that such an arrangement of the electrodes against the walls of the particulate filter, allows them to better withstand the flow of gas in these channels, the front part of these channels, ie the section the first in contact with the exhaust gas, being covered with a material catalytic impregnation, to trigger the oxidation of soot deposited in surface and in the pores of the filter media.

The rear part of the filter is associated with the means forming plasma discharge generator.

The electrodes of these means are held in position on the one hand, due to the fact that they pass through the end cap of the rear end input channels and secondly that their front end is embedded in the layer of dielectric barrier material.

It is of course conceivable that each input channel may contain a or several electrodes of each type.

These electrodes are, as previously indicated, connected electrically to a source of power supply.

This power supply is of the type for example impulse, to a frequency ranging from one-shot to several tens of KHz for a high voltage applied, for example several tens of KV and low intensity and short duration.

It will also be noted that an additive to aid the regeneration of the filter can also be mixed with fuel to facilitate the spread of the burning with soot.

The power supply for triggering operation means for generating plasma discharges, may be sinusoidal type or continue.

The impregnating material deposited on the front part of the channels inlet of the filter, can be a catalyst for oxidation of soot.

It can also allow the oxidation of soot and the depollution of hydrocarbons and CO. It can also be coupled to a reduction function nitrogen oxides.

It is conceivable then that such a structure makes it possible to solve a certain number of problems of the state of the art by optimizing the processing of soot, that is to say starting from the observation that the deposit of soot is more important at the bottom of the filter at the entrance to it and using in this area, means for generating plasma discharges.

Moreover, the regeneration of the particulate filter can also be ensured without implementing a post-fuel injection strategy in the engine cylinders during their relaxation phase, which improves the performance in terms of fuel consumption of it.

Of course, other embodiments may be envisaged.

Thus, for example, the layer 5a of impregnation material deposited on the input channels can have a homogeneous charge or not ("zoning"), for example with a lower metal load on the entrance part of the channels and more important on the back part of this layer of catalytic material, to meet a need for regeneration efficiency of the deposited soot on this one, this bed being finer on the entry of the channels than on the end of the layer.

Such a treatment system can also be supplemented by a system for the treatment of gaseous pollutants emitted by the combustion engine internal.

Indeed, the catalytic impregnation on the front face of the inlet channels allows the combustion of soot while impregnation of the entire surface exit channels can help control HC and CO emissions (oxidative type catalytic formulation), and NOx reduction (formulation catalytic reductive type).

In this case too, the distribution of metals in the coating can also be homogeneous or not ("zoning"), the most close to the output of the outlet channels being the most loaded with metals.

The purification member may comprise a filtering material produced in the form of a ceramic based on silicon carbide, silicon nitride, mullite, and preferably, for example, cordierite.

In the exemplary embodiment described, the input channels and the channels output of the purification member are square section.

Of course, other sections can be envisaged as per for example, input channels of hexagonal section or other.

The electrodes are advantageously made of stainless material, the anode forming electrodes being intended to be brought to the positive potential and the cathode electrodes being intended to be connected to ground.

The anode forming electrodes can then be connected to a generator of high voltage pulses as has been described.

Claims (10)

A system for purifying the exhaust gases of a motor vehicle engine, of the type comprising a gas purification unit, arranged in an exhaust line associated with the engine and comprising inlet gas channels (1) for purifying, having an open front end and a closed rear end (3), and outlet channels (2) purified gases having a closed front end (4) and an open rear end, and associated with catalyst means of oxidation (5a) and plasma discharge generating means (6, 7) for the regeneration of the purification member, characterized in that the catalyst means is in the form of a layer (5a) of catalytic impregnating material deposited on the open end end side of the inlet channels (1), and the plasma discharge generating means are in the form of electrodes (6, 7) vented on the closed rear end (3) side of these input channels (1), embedded in a layer of dielectric barrier material (5b) and connected to a power source. System according to claim 1, characterized in that the electrodes (6, 7) of the plasma discharge generator means and the layer of dielectric barrier material (5b) extend along the input channels over at least one third the length of these and that the catalytic coating layer (5a) extends over the remainder of the length of these channels. System according to Claim 1 or 2, characterized in that the electrodes (6, 7) are adapted to pass through the closed end (3) of the inlet channel (1). System according to any one of the preceding claims, characterized in that the electrodes are formed of at least one cathode and one anode in each input channel. System according to Claim 4, characterized in that the purification unit comprises several stacked rows (8, 9, 10) of successive input and output channels of square section, and that the electrodes of the input channels , are placed in opposite corners of each input channel, respectively, at the top or at the bottom, and to the left or right of the channel, so that the corresponding electrodes of two stacked rows are closest to each other . System according to any one of the preceding claims, characterized in that the purification element is a particulate filter. System according to any one of the preceding claims, characterized in that the outlet channels are coated throughout their length with a catalytic impregnation layer. System according to one of the preceding claims, characterized in that the dielectric barrier material is formed of a metal-free catalytic impregnating material. System according to one of the preceding claims, characterized in that the thickness of the dielectric barrier material layer (5b) is less than or equal to that of the catalytic material layer (5a). Exhaust line for motor vehicle engine, characterized in that it comprises a system according to any one of the preceding claims.

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