DE3936421A1 - Successive sections of ceramic exhaust pipe collecting soot - for burning off soot, operates electrically, electrostatically or magnetically to catalytically purify fumes - Google Patents

Abstract

Exhaust fumes taken with soot particles e.g. from an IC engine (1) enter the first section (5) of an exhaust line made of ceramics or mixed material which is electrically chargeable or magnetisable, causing the soot particles to adhere. This section (5) of exhaust pipe carries external thermal insulation (3) and leads to an uninsulated second section (7), made in this case of ceramic material to which soot particles attach electrostatically. At least one of the surfaces (5, 7) is made of NOX catalyst and/or oxidn. catalyst. The first exhaust section (5) is electrically heatable in zones. Heat insulation between the two sections (5, 7) is by an intermediate sleeve (8) with lower electrical resistance than the first section. ADVANTAGE - Soot collect only in specified areas to a given depth, in an exhaust with low pressure loss. Exhaust cleaning is improved, esp. at idling speeds, with deposited particles burning off.

Description

The invention relates to a device for removing Soot particles from exhaust gases in a combustion chamber combustion process taking place, for example at a diesel or petrol engine, where the particles accumulate attach to a separation surface and be removed from there.

It is known to exhaust diesel gases through porous ceramic walls respectively. The soot particles separate from these. Such surface filters bring a high Flow resistance for the exhaust gas with itself.

Filters are also made of ceramic fibers (Depth filter) known. Their flow resistance is true smaller than that of surface filters, but increases in Course of operation. For the regeneration of the well-known filters the accumulated soot particles are burned off. The  Burning requires a temperature greater than 600 ° C. A such exhaust gas temperature is in partial load operation, for. B. one Diesel engine hardly reached. It is therefore known that Initiate combustion by an additional burner, or the burning temperature by injecting a Lower oxidizing agent.

To the necessary power of the additional burner too limit, it is known to have two filter units in parallel to switch and regenerate them alternately. A however, such a facility is expensive.

Electrofilters are also known for cleaning exhaust gases. In these, particles of the exhaust gas are spray electrodes electrically charged, so that they are connected to a Separate the precipitation electrode.

In DE-PS 14 76 475 is a device for afterburning described by exhaust gases. With this one Afterburning can be achieved without a special heating source. For this it is a special mixing of exhaust gases and Air is provided on surfaces made of catalytic material. It an additional ignition element is required.

The object of the invention is to provide a device of the beginning to propose the type mentioned, in which the pressure loss in Exhaust gas low, the flow resistance is small and in which the removal of the particles in partial load operation is improved.  

Furthermore, it is an object of the invention to specifically target the soot deposit the separation surfaces of the facility, d. H. in certain layer thicknesses and in certain areas.

According to the invention, the above object is achieved in that a the combustion chamber near a separating surface Exhaust gas passage line is provided, which consists of a electrically rechargeable or magnetizable, ceramic Material and / or a composite material on which the particles mechanically and / or electrostatically and / or attach magnetically. This will remove the Soot particles from the exhaust gas possible in a simple manner without that there is a high flow resistance for the exhaust gas.

The soot particles collect in a simple embodiment in a preferably releasably connected to the device interchangeable collector or filter if necessary conventional type, but with greater open porosity, because the deposition of the soot particles essentially electrostatically or magnetically. For this can after reaching a certain level Burn it down or remove it in any other way.

A preferred embodiment is characterized in that that a first separation area close to the combustion chamber an exhaust gas passage line is provided that the first Separation surface from an electrically chargeable and / or magnetizable, ceramic material and / or a  Composite material, on which the particles mechanically and / or electrostatically and / or magnetically attach that the first separation surface in the direction of Exhaust gas flow in the exhaust passage line a second Separation area follows and that the first separation area is thermally insulated against the second separation surface.

Composite are z. B. composite body from one ceramic carrier material, for example ceramic fibers or to understand glass fibers with suitable electrical rechargeable and / or magnetizable and / or catalytic acting metals are infiltrated.

The particles are separated on the separation surfaces, which extend in the direction of the exhaust gas flow. The Separation areas thus increase the flow resistance of the Exhaust gas passage pipe and thus the pressure losses in the Exhaust gas flow does not. Since the first separation area is the Combustion chamber is nearby and opposite the second Separation surface is quickly and thermally insulated thus also a higher temperature than during partial load operation the second separation area. This promotes burning of the particles attached to the first separation surface. With this burning off on the first separation surface accumulated particles is a temperature increase in the Exhaust gas flow connected to the second separation area acts so that the particles deposited there also burn off.  

The first separating surface and / or preferably form the second separation area itself peripheral parts of the wall of the Exhaust duct. The thermal insulation between the first separation area and the second separation area in an embodiment of the invention by an intermediate piece formed, whose thermal conductivity is lower than that of first separation area.

In a preferred embodiment of the invention, the first is Separation surface on its outer circumference with a provided heat-insulating layer. This is the Heat dissipation from the first separating surface reduced to the outside. This increases the temperature of the first separation surface all in part load operation, so that their temperature rise in Direction towards those necessary to burn off the particles Temperature is accelerated.

In a further embodiment of the invention, the first Separation surface can also be electrically heated. This can preferably be achieved in that the material the first separation surface has an electrical resistance has by applying an electrical voltage the first separation surface leads to its heating.

An electrically conductive ceramic on the basis of SiC with the addition of ZrO ₂ and / or Si is suitable for the first deposition surface.

The first separation area and / or the second Separation area does not have to be in every case Form peripheral parts of the exhaust gas passage pipe. At larger exhaust gas mass flows or high particle density can be the first separation surface and / or the second Separation surface of tube bundles or plate layers in of the exhaust gas passage line.

If the electrical charge of the particles is not theirs Attachment to the electrically charged first Separation area or second separation area is sufficient A spray electrode can be provided in the exhaust gas flow desired electrical charge of the particles leads.

An embodiment of the invention results from the following description. The figure shows a device for post-combustion in a combustion chamber schematically.

A manifold ( 3 ) is connected to a cylinder ( 1 ) of a diesel engine as an exhaust gas passage line ( 2 ) and merges into a pipe section ( 4 ).

The manifold ( 3 ) consists of an electrically conductive and thus electrically chargeable, ceramic material. Its wall forms a first separation surface ( 5 ). The separating surface ( 5 ) is enclosed by a heat insulation layer ( 6 ), for example made of ceramic fiber material.

The pipe section ( 4 ) forms a second separation surface ( 7 ). It consists of an electrically conductive, ceramic material. A heat-insulating intermediate piece ( 8 ) made of ceramic material is arranged between the first separation surface ( 5 ) and the second separation surface ( 7 ). This prevents heat from flowing away from the first separation surface ( 5 ) onto the second separation surface ( 7 ).

The separating surface ( 5 ) is connected via an electrical connection ( 9 ) to the positive pole of an electrical direct current source. The second separating surface ( 7 ) is also connected to the positive pole of the direct current source via an electrical connection ( 10 ), it being assumed that the particles of the exhaust gas leaving the cylinder ( 1 ) carry a negative charge.

Furthermore, there is a further electrical connection ( 11 ) on the first separation surface ( 5 ), sufficiently spaced from the electrical connection ( 9 ). This is connected to the negative pole of the direct current source via a switch ( 12 ). When the switch ( 12 ) is closed, a current flows through the first separation surface ( 5 ) and heats it up. Here, the intermediate piece ( 8 ) is electrically insulating in order to avoid a simultaneous flow of current over the second separation surface ( 7 ).

The operation of the device described is approximately the following:  

When the diesel engine is in operation, hot exhaust gases containing particles are pushed out of the cylinder ( 1 ) or cylinders ( 1 ) into the manifold ( 3 ). The first separating surface ( 5 ) heats up quickly in the desired manner even during the starting process and in part-load operation of the diesel engine. The intermediate piece ( 8 ) suppresses heat flow onto the second separation surface ( 7 ). The heat insulation layer ( 6 ) prevents heat radiation into the environment.

The negatively charged particles contained in the exhaust gas accumulate on the first separation surface ( 5 ) and on the second separation surface ( 7 ).

After a short time, the heat build-up on the first separation surface ( 5 ) reaches a temperature which is substantially higher than the temperature on the second separation surface ( 7 ) and which is sufficient to burn off the particles deposited on the first separation surface ( 5 ). If, in special cases, the temperature is not reached quickly enough, the switch ( 12 ) is closed, whereby the first separation surface ( 5 ) is additionally heated.

By burning off the particles deposited on the first separation surface ( 5 ), the temperature in the second separation surface ( 7 ) increases, so that the particles deposited there also burn off.

The described device ensures that the particles burn off again and again even in the part-load operation of the diesel engine without the particles leading to blockages and the flow resistance in the exhaust gas passage pipe ( 2 ) increasing significantly.

The separating surface ( 5 ) and / or the separating surface ( 7 ) can also consist of a magnetizable, ceramic material. In this case, the particles settle under the action of a magnetic z. B. also electromagnetic field. As in the case of electrostatic charging, the accumulation can also be supported by a mechanical action based on the movement of the particles in the exhaust gas stream.

The separating surface ( 5 ) and / or the separating surface ( 7 ) can be made from a corresponding composite material together with the exhaust gas passage line ( 2 ). The separating surface ( 5 ) and / or the separating surface ( 7 ) can at the same time also form NO _x catalysts and / or oxidation catalysts.

In order to heat the separating surface ( 5 ) and / or the separating surface ( 7 ) for burning off the deposited particles, an electrical heating in individual zones can suffice.

Claims (11)

1. Device for removing soot particles from exhaust gases from a combustion process taking place in a combustion chamber, for example in a diesel engine or gasoline engine, the particles accumulating on a separation surface and being removed from it, characterized in that a separation surface ( 1 ) close to the combustion chamber ( 1 ) 5 ) is provided on an exhaust gas passage line ( 2 ), which consists of an electrically chargeable or magnetizable, ceramic material and / or a composite material on which the particles attach mechanically and / or electrostatically and / or magnetically. 2. Device according to the preamble of claim 1, characterized in that the combustion chamber ( 1 ) near the first separation surface ( 5 ) on an exhaust gas passage line ( 2 ) is provided that the first separation surface ( 5 ) from an electrically chargeable and / or magnetizable , ceramic material and / or a composite material on which the particles attach mechanically and / or electrostatically and / or magnetically, that the first separation surface ( 5 ) in the direction of the exhaust gas flow in the exhaust gas passage line ( 2 ) is followed by a second separation surface ( 7 ) and that the first separating surface ( 5 ) is thermally insulated from the second separating surface ( 7 ). 3. Device according to claim 1 or 2, characterized in that the separating surface ( 5 ) is electrically heated in zones. 4. Device according to one of the preceding claims, characterized in that the first separating surface ( 5 ) and / or the second separating surface ( 7 ) itself form peripheral parts of the wall ( 3 , 4 ) of the exhaust gas passage line ( 2 ). 5. Device according to one of the preceding claims 2 to 4, characterized in that the thermal insulation between the first and the second separating surface ( 5 , 7 ) is formed by an intermediate piece ( 8 ) whose thermal conductivity is lower than that of the first separating surface ( 5 ) is. 6. Device according to one of the preceding claims, characterized in that the first separation surface ( 5 ) is provided on its outer periphery with a heat-insulating layer ( 6 ). 7. Device according to one of the preceding claims, characterized in that the first separation surface ( 5 ) is electrically heated. 8. Device according to claim 7, characterized in that the material of the first separating surface ( 5 ) has an electrical resistance value which leads to its heating by applying an electrical voltage to the first separating surface ( 5 ). 9. Device according to one of the preceding claims, characterized in that the second separating surface ( 7 ) consists of an electrically chargeable, ceramic material on which particles accumulate electrostatically. 10. Device according to one of the preceding claims, characterized in that a spray electrode is provided which electrically charges the particles in the region of the first separation surface ( 5 ). 11. Device according to one of the preceding claims, characterized in that the separating surface ( 5 ) and / or the separating surface ( 7 ) are designed as NO _x catalysts and / or oxidation catalysts.