DE19846115A1 - Diesel particle removal apparatus for diesel exhaust fumes, comprises sound source with standing wave discharging through outlet pipes - Google Patents

Abstract

The apparatus absorbs particulate matter contained in e.g. diesel exhaust gases passing through a resonant pipe (1) which has a sound source (2) generating a standing pressure wave. The standing wave captures particles as these pass along the pipe, discharging to a discharge system (6,7) comprising several parallel pipes (6). The collected particles are returned to the combustion source.

Description

The invention relates to a device for absorption of particles contained in a gas stream, in particular of Soot particles, such as in the exhaust gas stream of an internal combustion engine a diesel engine, a motor vehicle are included.

The absorption of soot particles from an exhaust gas stream is particularly great especially for diesel engines of motor vehicles one for reduction the common and required measure of particle emissions in order to to comply with the prescribed limit values set by the mass or the number of emitted particles can be defined. The latter takes into account the fact that especially the small particles responsible for health and environmental damage the. There is therefore a need for a device with which gera de also relatively small particles contained in a gas stream are reliably absorbed.

From the published documents DE 38 18 158 A1 and DE 39 41 635 are devices of this type for the absorption of egg gas Nes diesel engine contained soot particles known to this Purpose to include a soot filter. The soot separated in the filter is from time to time through an adabatic temperature increase burned down by a blast using two coupled Helmholz resonators is effected.

The invention is a technical problem of providing a comparatively simple and effective facility for Absorption of particles contained in a gas stream.  

The invention solves this problem by providing a Device with the features of claim 1. In this one direction is at least one resonance tube in the flow path of the Gas flow arranged in which of an associated sound source a standing pressure wave can be generated. Through this The pressure wave can be contained in the gas stream flowing through particles, in particular also comparatively small particles, capture very effectively and distribute locally and so on with filter out of the gas stream. The one from the blast wave trapped particles can then be removed by suitable particle removers be removed from the resonance tube.

In a device further developed according to claim 2 the particle removal means a discharge line system that on the inlet side consists of several parallel line branches, that at places of maximum particle accumulation in the resonance tube protrude into it. These lines can be used in the Reso Particles collecting particles are discharged from this. In an advantageous, suitable for exhaust gas purification training this measure according to the invention is according to claim 3 from guide line system on its outlet side to the combustion source returned to the from contained particles to reini emitting exhaust gas flow. This allows exhaust gas cleaning supply in the form of exhaust gas recirculation in the combustion process realize.

A device developed according to claim 4 has little at least two parallel resonance pipes with respective sound sources and a flow control unit with which the of Parti The gas flow to be cleaned is optionally in one or the other Resonance tube can be initiated. The particle removal means contain suitable control means for this, the syn chronically with the switching of the flow control unit the sound Switch sources on and off, d. H. the sound source is active fourth when the gas flow into the resonance tube associated with it is routed, and otherwise deactivated. In the inactive period clear the sound source in which the gas flow is not through the  associated resonance tube flows, the total in the latter mixed particles are easily removed, e.g. B. by going into one collecting container fal len.

Advantageous embodiments of the invention are in the Drawings are shown and are described below. Here show:

Fig. 1 is a schematic side view of a device for sorption from contained in a gas stream particles with a single resonance pipe and a Ableitleitungssy system and

Fig. 2 is a schematic side view of a device for sorption from contained in a gas stream particles with two parallel resonance tubes and associated particle collection containers.

The devices shown in FIGS. 1 and 2 are particularly suitable for the absorption of soot particles contained in an exhaust gas stream of a motor vehicle diesel engine, but can also be used for other cases where particles entrained by a gas stream are to be removed from it, e.g. . B. also in exhaust gas cleaning systems of stationary combustion plants. The device according to the invention, as exemplified by the two implementations shown, is based on the known functional principle of the Kundt tube. In the latter case, a standing, longitudinal sound pressure wave is generated in a gas-filled pipe. The maxima and minima of the course of the velocity of the gas particles in the tube lie in the nodes of the pressure wave, while the gas particles do not move in the region of the maxima and minima of the pressure wave. If particles are now added to the tube, the pressure wave creates a defined, locally non-uniform distribution of the particles, which is used as an indicator of the presence of the pressure wave and z. B. can also be used to determine the wavelength.

The invention uses a reversal of this effect by one or more resonance pipes are provided, through which one of Particles to be cleaned gas stream is passed and in which a respective standing, longitudinal sound pressure wave can be generated. With this pressure wave it is then possible to trap particles contained in the gas stream passed through, d. H. by the effect of the pressure wave from another Mitrei to be stopped by the gas flow. The tuned pipe absorbs thus the particles contained in the gas stream passed through at least largely, with those collecting in the resonance tube Particles can be removed appropriately from this. By ent speaking setting of the resonance frequency of the sound wave can the sensitivity to particle size is influenced by who the, d. H. the resonance frequency can be suited to the middle The size of the particles to be absorbed can be adjusted. In order to it is comparatively easy to do, even relatively small soot to absorb particles from the exhaust gas of a combustion source.

Fig. 1 shows an embodiment that includes a single resonance tube 1 , at one axial end of a sound source 2 is positioned. At the opposite axial end face of the resonance tube 1 is closed, and a radially opening out inlet 3, the stream of particles to be cleaned gas 4 introduced into the tube. 1 From there, the introduced gas 4 flows to the sound source-side axial end region of the raw res 1 and leaves it as a particle stream 4 a cleaned via a radial outlet 5 .

To accomplish the particle absorption is activated by activating the sound source 2, a sufficiently strong acoustic vibration in the resonance tube 1 , which leads to the formation of a standing, longitudinal sound wave. This sound wave captures the particles contained in the gas stream passed through, ie holds them in place, so that the gas leaves the tube 1 again as part-cleaned. The particles accumulate in the maxima and minima of the pressure wave, since the speed of the gas particles moved by the pressure wave is lowest at these points.

A discharge line system for discharging the particles trapped in the resonance tube 1 is provided which has a plurality of parallel line branches 6 on the inlet side, each of which protrudes into the area of the maximum particle accumulation into the resonance tube 1 on the mouth side. The parallel discharge line branches 6 are substantially perpendicular to the resonance pipe longitudinal axis on the circumferential side out of the resonance pipe 1 and open into a common discharge manifold 7 . The particles captured in the resonance tube 1 by the sound wave can be discharged in this way as a particle stream 8 through the discharge system. If the gas stream 4 to be cleaned of particles originates from a combustion process, for example a stationary furnace or an internal combustion engine, a return of the particle stream 8 to the combustion process can advantageously be provided in order to subject the particles there to a renewed oxidation.

The exemplary embodiment shown in FIG. 2 includes two resonance tubes 9 , 10 arranged vertically with their longitudinal axis, each with its own sound source, 11 , 12 arranged at the upper front end. In the lower end region, the resonance tubes 9 , 10 each have a radially opening inlet 13 , 14 , the inlets 13 , 14 extending on opposite sides of a flow guide unit in the form of a flow guide flap 15 which can be pivoted in a controlled manner. With this flow guide flap 15 can be supplied via a supply line 16 , from particles to clean gas stream 17 optionally via one inlet 13 in the egg ne resonance tube 9 when the flap 15 is in the solid end position, or through the other inlet 14th be passed into the other resonance tube 10 when the flap 15 is in the other end position 15 a shown in dashed lines. In the vicinity of the upper end face a common deceleration outlet 18 is provided for the two resonance pipes 9, 10, consisting of a the pipes 9, 10 connecting cross line and a perpendicular from this outgoing discharge line. Via the sen outlet 18 , however, one or the other of the resonance tubes 9 , 10 guided and cleaned of particles there can be discharged as a substantially particle-free gas stream 17 a. Furthermore, for each resonance tube 9, 10, a particle collecting container 19, 20, the gas close to the axially open lower end face of the respective resonance pipe 9, 10 is connected.

With this device according to FIG. 2, a very simple and effective removal of the particles from the resonance tubes 9 , 10 is possible. For this purpose, the gas stream 17 to be cleaned of particles is alternately introduced into one and into the other resonance tube 9 , 10 by a corresponding control unit, not shown, for which purpose the flow guide flap 15 is controlled accordingly by the control unit. The switchover of the introduction of the gas stream 17 from one to the other resonance tube occurs at the latest when the currently active resonance tube, through which the gas stream is currently passed, is largely saturated with absorbed particles captured by the sound pressure wave. This can be determined empirically beforehand or metrologically during operation, so that the circuit follows, for example, at fixed time intervals or when the particle concentration measured in the gera de active resonance tube has exceeded a certain threshold value.

Corresponding to the control of the flow guide flap 15 who the sound sources 11 , 12 from the control unit so that the sound source is always activated and the necessary, strong, standing longitudinal sound pressure wave, it generates the current gas stream 17 to be cleaned through the resonance pipe is assigned, while the other sound source remains switched off during this period. If, when switching over, the previously activated sound source of the resonance tube, which has long been exposed to the gas stream and contains the particles which have been absorbed in the meantime, is switched off and at the same time the gas flow introduction into this tube is terminated, the sound pressure wave formed up to now breaks down and the particles held by it fall due to their gravity down into the collecting container 19 , 20 , where they can be removed. At the same time, the required sound pressure wave is built up in the other resonance tube by switching on the sound source belonging to it and the gas stream 17 to be cleaned is diverted into this tube.

Through this alternating operation of the two parallel resonance pipes 9 , 10 , a continuous absorption of particles of a supplied gas stream 17 can be effected with periodic removal of the absorbed particles without having to be interrupted here for the gas stream supply and without the need for a special discharge line system .

It goes without saying that in addition to the examples shown, further modifications and variants can be implemented within the scope of the invention. For example, the one or more parallel resonance tubes in the gas flow path can be preceded or followed by a customary particle filter. In addition, if necessary, more than two parallel resonance tubes and / or more serial resonance tubes can be provided with the principle of operation explained, the z. B. can be matched to different particle sizes. Wei ter it is possible instead of the particle collection container in Fig. 2 to provide a discharge line system according to the example of Fig. 1 or to replace the discharge line system in the example of Fig. 1 by a particle collection container of the type of the example of Fig. 2. In the latter case, a periodic short-term interruption of the gas supply is then expediently provided in order to switch off the sound source in these short interruption times, so that the particles previously held by the pressure wave fall into the collecting container.

Claims (4)

1. Device for the absorption of particles contained in a gas stream, in particular an exhaust gas stream, characterized by

• - At least one arranged in the flow path of the gas stream Re sonanzrohr ( 1 ),
• - A sound source ( 2 ) for generating a standing pressure wave in the resonance tube for trapping particles contained in the gas stream passed through and
• - Particle removal means for removing the particles captured by the pressure wave.

2. Device according to claim 1, further characterized in that the particle removal means contain a discharge line system ( 6 , 7 ) with a plurality of parallel, inlet-side line branches ( 6 ) which are guided on the mouth side to locations of maximum particle accumulation in the resonance tube ( 1 ). 3. Device according to claim 2 for the absorption of particles contained in a gas stream from a combustion source, further characterized in that the discharge line system ( 6 , 7 ) on the outlet side is fed back to the combustion source. 4. Device according to claim 1, further characterized in that

• - At least two parallel resonance tubes ( 9 , 10 ), each with an associated sound source ( 11 , 12 ) and a flow unit ( 15 ) for controllable, optional introduction of the gas stream ( 17 ) are provided in one or the other resonance tube and
• - The particle removal means a control means for periodically switching the flow control unit ( 15 ) between the introduction of the gas flow into one and into the other resonance tube ( 9 , 10 ) and for correspondingly activating the sound source of the respective gas-flowed resonance tube and deactivating the other sound source .