DE19536705A1 - Method for measuring particles in gas flow e.g. vehicle exhaust - Google Patents

Abstract

The method generates an electrical field between a hollow electrode (7,12), through which the gas flows, and an internal electrode (9,6) within the hollow electrode by the application of a constant d.c. voltage. The charging current required for maintaining a constant voltage between the electrodes is measured. The d.c. voltage required can be 2 to 3 kV and the charging current can be measured using a high value series resistance (8) in the current circuit as a shunt.

Description

The invention relates to a method and a device for quantitative Determination of the electrically conductive and / or contained in a gas stream charged particles, especially the soot particles in an exhaust gas electricity.

The electrical charge carriers or electrically conductive particles can Be components of the gas stream or for marking purposes Gas flow can be added in a predetermined amount, for example around the To measure volume flow or flow velocity. The particles can u. a. from metal dusts or ions generated in the gas stream be formed. The preferred application for the invention is however the quantitative measurement of soot particles in an exhaust gas stream, especially the exhaust gas flow of a diesel engine.

There are currently several for determining the soot particles in an exhaust gas stream re known process. An engine test bench is widely used guided measurement method in which a certain amount of exhaust gas flow passed through a filter paper and the blackening of the paper with a Photo sensor is determined. This process is very time-consuming (about 1 Minute for a measurement) and due to the complex and sensitive Devices only suitable for laboratory use.

Furthermore, other optical measuring methods for measuring the Turbidity of the exhaust gas flow tested. All of these procedures require one quite complex measuring equipment and are against contamination of the optical equipment very sensitive due to soot deposits. Out for this reason the practical use of these soot measuring methods on diesel engines in series vehicles are not yet possible.

The object of the invention is a measuring method and a measuring device to create that with no significant time lag with simple and insensitive means a reliable measured value set the amount of elec. contained in any gas stream trically conductive and / or charged particles. Another important object of the invention is a measuring method and a Meßvor to create direction, which for soot measurement on diesel engines of series vehicles can be used.

This object is achieved by the fol following steps:

• a) Generating an electric field between one of the gas current flowing through the jacket electrode and an inner elec trode within the jacket electrode by applying a constant DC electrical voltage;
• b) Measuring the charging current to maintain the constant DC voltage between the jacket electrode and the internal electrical system de.

As soon as the electric field from a gas stream with electrically conductive or charged particles is flowing through, the elec will malfunction trical field, which the electric field strength and the voltage between influenced both electrodes. Since this tension is caused by a suitable te control device is kept constant, a charging current between the electrodes and the voltage source flow. This stream represents the amount of particles contained in the gas stream and can with simple Means are measured.

In contrast, the electric field between the jacket electrode and the Particle-free gas flow flows through the inner electrode no disturbance of the electric field instead, so that no measurable charging  electricity flows. This applies essentially to the entire measurement an engine exhaust gas flow relevant temperature range.

When using the method according to the invention on a diesel engine preferably a metallic exhaust pipe of the engine as the jacket electrode used. The inner electrode should be in the area of the center line of the Ab be arranged gas pipe, so that a coaxial, static electric field arises. In the first attempts, in which the soot particles in the exhaust gas flow of a diesel engine were measured, good measurement results were achieved be when generating a DC voltage of 2000 to 3000 volts of the electric field was used.

The physical processes on which the disturbances in the experiments occurred of the electric field due to the soot particles, have not yet been able to be examined in detail. Several alternatives come into question. Possibly point out the combustion chamber of the Diesel engine exiting soot particles on an electrical charge that electrical field disturbs or that when flowing through the electrical field is transferred to the jacket or inner electrode. It is also possible, that neutral soot particles become charged in the electrical field or electrostatically charged soot particles their charge state in the elec change trical field so that the elec. without contact with the electrodes trical field supplied by the exhaust gas flow or is removed.

To measure the charging current you can choose between a voltage output DC voltage source and one of the two electrodes a high impedance Working resistance can be switched on which the voltage change is measured based on the charging current. In the experiments mentioned the input resistance of an oscilloscope was used with a 1 megohm resistance. With slight blackening of the diesel engine A measuring voltage of 500 mV could be measured in the exhaust gas.  

The respective measuring voltages can experimentally correspond to them be assigned to the values for the amount of particles in the gas so that the measuring device instead of the measuring voltage directly the particle content or at motor measurements quantitatively indicate the soot emission. At motori cal measurements, the measuring voltage is preferably an electronic Control system of a vehicle diesel engine supplied and for determination the optimal manipulated variables such as injection quantity, start of injection and on spray pattern used.

A device according to the invention comprises the features of claim 5, wherein according to claim 6, the jacket electrode in motor measurements preferably formed by the exhaust pipe of the internal combustion engine itself becomes.

There are both high temperatures in the exhaust pipe of a diesel engine as well as high accelerations due to engine vibrations. thats why the measuring device according to the invention for use in production vehicles training as robust as possible. It lends itself to the construct experience of other electrical motor accessories, namely Zünd candles to fall back on. For the voltage supply to the exhaust pipe and An electrode support can be used inside the electrode External electrode by means of a positive connection to the exhaust gas Pipe is attached and its center electrode against the insulator Outer electrode is insulated. The center electrode extends into the middle Area of the exhaust pipe and is electrically conductive with the interior Electrode of the measuring device according to the invention connected.

The electrode carrier can also be located in the exhaust pipe Sheath electrode and an inner electrode enclosed by it ver be bound. In this case, it must be electrically insulated from the exhaust pipe if the jacket electrode is on another during the measurement ren voltage level than the exhaust pipe.  

The inner electrode preferably has no sharp corners, edges or Spikes, because there are corona discharges due to a too high Can form charge concentration, which interfere with the measurement process. Around The internal electrode is to prevent the corona discharges as far as possible to be spherical.

During the first measurements with an uninsulated inner electrode after a short while, there are electroconductive soot deposits on the insulator of the electrical conductor leading to the inner electrode formed. As a result, the electrical resistance between Electrode and inner electrode quickly dismantled and the electric field collapsed. For this reason, measures must be taken which builds up an electrically conductive soot layer between the cladding Avoid the electrode and the inner electrode. Because the physical processes the disturbance of the electric field has not yet been finally investigated cannot be predicted with certainty whether it is necessary that the conductive surfaces of both electrodes with the charge exchange the particles must be in contact with the gas flow. Should this be the Case, the formation of a closed particle layer between the inner electrode and the jacket electrode can be prevented that a cover is provided which covers the inner electrode and / or at least the electrical conductor connected to the inner electrode partially covers and shields against the gas flow. Through this stream upstream of the inner electrode and the electrical conductor de coverage will be the direct impact of those contained in the gas stream Avoid particles on the covered area. So that no particles by swirling behind the cover to the covered area trans ported, the gas flow is fresh air with a corresponding Supply pressure, which in the flow direction from the cover to the covered area of the inner electrode or the conductor flows and so prevents these parts from coming into contact with the gas flow.  

It is also possible to close the soot on the center electrode to avoid the wall of the exhaust pipe in that in the cavity of the electrode carrier, which surrounds the center electrode, fresh air under a pressure exceeding the pressure of the exhaust gas stream is initiated. The center electrode can also protrude from the wall of the Ab gas pipe radially inwardly extending pipe, which the direct flow against the center electrode prevented. The inflow of Particles in this tube can be made more difficult by the fact that Cover tube is designed as a corrugated tube, that is, the value of Diameter of the cover tube around an average diameter value fluctuates sinusoidally.

However, it is likely that to measure the disturbance of the electrical Field must have at most one electrode in contact with the exhaust gas flow. In this case, the second one, namely the inner electrode, can be completely be provided with an electrically insulating jacket. Also in In this case it may be necessary to use a cover to prevent the Soot deposits on at least a portion of the casing and provide the insulation of the electrical conductor, otherwise a closed soot film that surrounds the inner electrode and Electrode runs, can interfere with the build-up of the electric field.

Further features of the invention emerge from the subclaims and the following description of the drawing. The drawings show in

Fig. 1 is a schematic representation of a Parti kelmeßsystems invention on an exhaust pipe,

Fig. 2 is an illustration of an alternative embodiment of the Parti kelmeßsystems from Fig. 1,

Fig. 3 shows the electrode carrier from Fig. 2 with umman telter inner electrode and

Fig. 4 shows a further embodiment of the particle measurement system according to the invention with a jacket electrode insulated from the exhaust pipe.

The particle measurement system shown in FIG. 1 for the quantitative determination of the soot emission of a diesel engine comprises a DC voltage source 1 , the voltage of which is applied to the two electrodes of an electrode carrier. The electrode carrier consists of a metal formschlüssi gene fastening device, for. B. a bayonet lock, which is electrically connected to the exhaust pipe 7 and forms the outer electrode 4 . An insulator 3 is arranged within the outer electrode 4 , along the center line of which the center electrode 16 runs. This extends to the central region of the exhaust pipe 7 and is there connected to the tubular inner electrode 6 of the measuring device. So that no closed, electrically conductive particle film is deposited between the inner electrode 6 and the jacket electrode 7 , the wall of the outer electrode 4 of the electrode carrier is provided with ventilation holes 17 through which fresh air is led into the exhaust gas stream and the soot deposit at the lower part of the Isolators 3 is prevented. It must be ensured that the fresh air always flows out of the ventilation holes 17 into the exhaust gas flow. This can be achieved by using a compressor connected to the ventilation bores 17 (shown in FIG. 2 and described further below) 15 .

Between the negative voltage output of the DC voltage source 1 and the connection to the outer electrode 4 of the electrode carrier, a load resistor 8 is connected, at which the measuring voltage is tapped. A suitable analog or digital voltage measuring device can be connected to the measuring voltage connections 2 .

In FIG. 2, an alternative embodiment of the electrode carrier is shown with a spherical inner electrode 9. By using a spherical inner electrode 9 it is avoided that sharp edges or corners on the inner electrode 9 cause a local increase in the electric field strength and thus a corona discharge. The course of the electric field lines 5 when using the spherical inner electrode 9 is also shown.

Fig. 2 shows an additional ring-shaped cover 14 which prevents the deposition of the soot particles to the electrical conductor leading to the inner electrode 9. The cover 14 has the shape of a hollow cylinder which is open on its downstream side (the right-to-left flow direction of the exhaust gas flow is shown in all drawings by a large arrow). So that no vortices behind the cover 14 soot particles to the covered electrical conductor ren, the cover 14 is connected via an air line 13 to a compressor 15 which introduces compressed fresh air into the cover 14 . In this way, an area of the electrical conductor leading to the inner electrode 9 is permanently in a fresh air flow and cannot come into contact with soot particles.

FIG. 3 shows a further possibility of avoiding the soot particles deposit on the electrically conductive surface of the inner electrode 9 and the associated conductor 16. Starting from the insulator 3 of the electrode carrier, both the electrical conductor 16 and the inner electrode 9 are surrounded by an insulating jacket 10 . Since in the case of a closed soot layer on the casing 10, the charge on the casing 10 is displaced by the action of the electric field and the structure of the field between the casing electrode 7 and the inner electrode is disturbed, a cover must also be provided here .

In Fig. 4, a further alternative embodiment of the measuring device is shown, which forms a self-contained sensor system independent of the electrical potential of the exhaust pipe. The electrode carrier is connected here via an insulating foot 11 to the exhaust pipe 7 ', which is thereby galvanically isolated from the measuring device. The Außenelek electrode of the electrode carrier is connected to a within the exhaust pipe 7 'Liche, separate jacket electrode 12 . The central electrode 16 is connected to an oval inner electrode in the present case, which - as described above - has a casing 10 . Through the tubular, the center electrode 16 surrounds outer electrode can be prevented on the center electrode 16 carbon deposits. The inflow of exhaust gas into the outer electrode can be made more difficult by a wavy formation from the outer electrode.

The use of a separate, from the exhaust pipe 7 'insulated jacket electrode 12 has advantages for certain applications. First, it is possible to determine the amount of particles within a portion of the flow cross section of the exhaust pipe 7 '. So z. B. in a series of tests, the soot distribution over the entire cross section of the exhaust pipe 7 'can be determined. Secondly, because of the smaller space enclosed by the jacket electrode 12, a lower DC voltage is necessary in order to generate an electric field with a predetermined field strength between the inner and the jacket electrodes.

Reference list

1 DC voltage source
2 measuring voltage connection
3 isolator
4 outer electrode
5 field line
6 cylindrical inner electrodes
7 Exhaust pipe and jacket electrode
7 ′ exhaust pipe
8 working resistance
9 spherical inner electrode
10 sheathing
11 insulating foot
12 jacket electrode
13 air duct
14 cover
15 compressors
16 center electrode
17 ventilation hole

Claims (14)

1. Method for the quantitative determination of the electrically conductive and / or charged particles contained in a gas stream, in particular the soot particles in an exhaust gas stream, consisting of the following steps:

• a) generating an electric field between a gas flow through the jacket electrode ( 7 , 12 ) and an inner electrode ( 9 , 6 ) within the jacket electrode ( 7 , 12 ) by applying a constant DC electrical voltage;
• b) Measuring the charging current to maintain the constant DC voltage between the jacket electrode ( 7 , 12 ) and the inner electrode ( 9 , 6 ).

2. The method according to claim 1, characterized in that an equal Voltage from 2000 to 3000 volts to generate the electrical field is used. 3. The method according to claim 1 or 2, characterized in that a voltage source ( 1 ) generating the DC voltage is connected to one of the electrodes via a high-resistance resistor ( 8 ) and measured as a measurement signal of the voltage drop across the resistor ( 8 ) due to the charging current becomes. 4. The method according to at least one of the preceding claims, since characterized in that a the amount of soot particles in an exhaust gas measured value representing an electronic control system Internal combustion engine, especially diesel engine, is supplied.   5. A device for the quantitative determination of the electrically conductive and / or charged particles contained in a gas stream, in particular the soot particles in an exhaust gas stream, characterized by

• - A jacket electrode ( 7 , 12 ) through which the gas flow flows and an inside electrode ( 6 , 9 ) arranged inside the jacket electrode ( 7 , 12 ),
• - A DC voltage source ( 1 ), which is connected via electrical conductors on the one hand to the jacket electrode ( 7 , 12 ) and on the other hand to the inner electrode ( 6 , 9 ), and
• - A measuring device for measuring the charging current flowing from the DC voltage source ( 1 ) to the electrodes ( 6 , 7 , 9 , 12 ).

6. The device according to claim 5, characterized in that the jacket electrode is formed by an exhaust pipe ( 7 ) of an internal combustion engine. 7. The device according to claim 6, characterized in that on the exhaust pipe ( 7 ) with the DC voltage source ( 1 ) connected Elek electrode carrier is attached, which is connected to the exhaust pipe ( 7 ) outer electrode ( 4 ), one of the outer electrode ( 4 ) protruding insulator ( 3 ) and a center electrode ( 16 ) extending within the insulator ( 3 ), which is connected to the inner electrode ( 6 , 12 ) in the exhaust pipe ( 7 ). 8. The device according to claim 5, characterized in that on the exhaust pipe ( 7 '), an insulating base ( 11 ) of an electrode carrier connected to the DC voltage source ( 1 ) is attached, which one to the jacket electrode ( 12 ) in the exhaust pipe ( 7 ') has leading outer electrode ( 4 ) and a center electrode ( 16 ) insulated from the outer electrode ( 4 ), which is connected to the inner electrode ( 6 ). 9. The device according to at least one of claims 5 to 8, characterized in that the measuring device was a high-resistance working resistor ( 8 ) and has a measuring device, the working resistor ( 8 ) between a voltage output of the DC voltage source ( 1 ) and the man tel- Electrode ( 7 ) or the inner electrode ( 6 ) is connected and the Meßge advises the voltage across the load resistor ( 8 ). 10. The device according to at least one of claims 5 to 9, characterized in that corners, edges or tips of the inner electrode ( 9 ) are rounded. 11. The device according to at least one of claims 5 to 10, characterized in that a cover ( 14 ) is arranged in the flow direction of the exhaust gas upstream of the inner electrode ( 9 ) which the inner electrode ( 9 ) and / or of the inner electrode ( 9 ) leading electrical conductor at least partially, wherein fresh air is introduced into the cover ( 14 ). 12. The device according to at least one of claims 7 to 11, characterized in that the outer electrode ( 4 ) or the insulating foot ( 11 ) is provided with at least one ventilation hole ( 17 ), through the fresh air into the exhaust pipe ( 7 or 7 ' ) is initiated. 13. The device according to at least one of claims 5 to 12, characterized in that the leading to the inner electrode ( 9 ) electrical conductor from one of the wall of the exhaust pipe ( 7 , 7 ') radially into the exhaust pipe ( 7 , 7 ') extending tube, preferably corrugated tube is surrounded. 14. The device according to at least one of claims 5 to 13, characterized in that the inner electrode ( 9 ) is provided with an electrically insulating the casing ( 10 ).