DE3319186A1 - METHOD FOR GENERATING A REFERENCE POTENTIAL IN POTENTIOMETRIC LAMBDA PROBE - Google Patents

Abstract

In said method, the measuring electrode and the counter-electrode are exposed to exhaust gas and present an adjustment which causes alternating changes between the rich and lean operations. Furthermore the counter-electrode is so arranged that the sensitive time and the dead time upon the passage of gas from the rich to the lean operation deviate from the sensitive time and the dead time upon the gas passage from the lean to the rich operation. Therefore, the counter-electrode has asymmetric sensitive times. A rich reference is preferably used wherein the sensitive time and the dead time upon the gas passage from the lean to the rich is shorter than the passage from the rich to the lean. Furthermore, the counter-electrode is provided with an anti-diffusion layer which presents pores having diameters which are small with respect to the mean free travelling length of oxygen molecules. Thereby, the measuring electrode does not make loop oscillations in the rich to lean direction and generate a substantially constant potential which may be used as a reference potential for the probe.

Description

Method for generating a reference potential

prior art in potentiometric lambda sensors. The invention is based on a method according to the preamble of the main claim. The most common so far The type of lambda probe uses the partial pressure of oxygen in the air as a reference The counter electrode of these probes is therefore in contact with the outside air. The construction of Lambda probes will be simpler if it is possible to use both the measuring electrode as well as exposing the counter electrode to the exhaust gas. This also makes it easier to to move from a tubular structure to a plate-shaped structure. It However, the difficulty arises in finding a reference potential at the counter electrode from the same gas to which the measuring electrode is exposed. here various possible solutions have already been proposed. For example, shows DE-OS 25 47 683 a counter electrode made of a catalytically inactive material exists, so that between this electrode and the catalytically active measuring electrode a potential difference results, The disadvantage of such a solution However, it can be seen in the fact that there are hardly any materials that are catalytic for a long time are inactive, as these materials gradually get a certain amount due to the operating conditions acquire catalytic activity so that the reference potential gradually shifts. From DE-OS 30 40 494 the possibility has become known, a potentiometric Lambda probe with a polarographic sensor, a so-called limit current probe to combine in order to always have one on the counter electrode of the lambda probe To have oxygen concentration O. However, this solution has the disadvantage that it it is necessary to have a direct voltage on the limit current probe for the entire operating time of the probe to provide for the generation of the pumping current. After all, it is, for example from DE-OS 21 15 619, known, the oxygen partial pressure of a metal / metal oxide mixture to be used as a reference in order to be independent of atmospheric oxygen, for example if the installation location of the probe makes it difficult to achieve an air reference is. However, such a metal / metal oxide reference has the disadvantage that the The proportion of metal to metal oxide gradually shifts, so that the point in time comes in which only metal or only metal oxide is present, so this reference is no longer functional.

Advantages of the invention The method according to the invention with the characterizing Features of the main claim has the advantage that here neither the consumption of a substance can still inhibit the function of the reference through a gradual Activation of the counter electrode a shift in the reference potential occurs. It is also not necessary to have a DC voltage during the entire operating time of the probe to provide. A prerequisite for using this procedure is However, that a regulation is provided that a constant change between fat and lean with a constant frequency.

The measures listed in the subclaims are advantageous Further developments and improvements of the method specified in the main claim are possible.

It is particularly advantageous if the counter electrode is provided with a diffusion-inhibiting one To cover layer, i.e.

to use a so-called fat reference, in which the response time (here and in the following, the term "response time" always includes the sum of the response time and dead time) during the transition of the measuring gas from lean to rich is shorter than the response time when going from rich to lean, since engines generally start in rich form and thus the transient process that leads to the control oscillations mentioned above leads, is facilitated. In order to make this transient process even easier, it can be advantageous to have a DC voltage in the first few seconds after the start to generate a pumping current to apply to the electrodes in order to achieve the to accelerate bold reference potential. The same also applies to the case that a lean reference is used. In addition, it can also be beneficial be able to create the inventive method with any of the conventional methods of a reference potential combine, as on the one hand in the case of one Metal / metal oxide mixture this is not used up so quickly, on the other hand but you can operate the lambda probe at lower temperatures than without it the inventive method is possible because the reference potential is already at a lower temperature is reached.

DRAWING Two exemplary embodiments of the invention are shown in the drawing shown and explained in more detail in the following description. It show figure 1 the simplified representation of a lean reference, FIG. 2 schematically the voltage / time curves this lean reference, Figure 3 function curves of the lambda probe, Figure 4 the simplified Representation of a bold reference and, finally, FIG. 5 schematically the voltage / time curves the bold reference according to Figure 4.

Description of the exemplary embodiments In Figure 1 is a lean reference, i.e. a counter electrode in which the response time at the transition of the measuring gas from rich to lean is shorter than the response time when transitioning from lean to in bold. The lambda probe consists of a plate 1 made of stabilized Zirconium dioxide, on the one hand, the measuring electrode 2, which is known per se Way can consist of platinum or a platinum-zirconium dioxide mixture, carries. At the measuring electrode 2 is followed by a conductor track 3 for the electrical connection of this Electrode. The opposite side of the plate 1 carries the counter electrode 4, which corresponds in its structure to the measuring electrode 2 and to which the electrical Contacting a conductor track 5 connects. The electrode 4 is about halfway covered with a gas-tight glaze 6, for example made of a barium borate glass. At the transition of the measuring gas from rich to lean, which is at this counter electrode If it plays quickly, the following processes occur: First, the electrode shows the rich exhaust gas over its entire area over an oxygen partial pressure of around 10 15bar. If now at the transition of the measuring gas from rich to lean the oxygen partial pressure to 10 bar - this corresponds approximately to the point? L - 4 increases, this corresponds to a transport of only a few oxygen molecules the uncovered electrode part to the part covered with the gas-tight layer 6, so that it is easy to see that this process, in which only a few. Oxygen molecules have to diffuse, runs quite quickly. In Figure 2, in which the voltage test run of the counter electrode (measured against an air electrode) plotted against time you can see this very clearly at curve 7. Starting from a high voltage from, for example, 800 mV, the voltage drops very quickly to a value of around 200 mV in order to then asymptotically approach the equilibrium value. This matches with then about an oxygen partial pressure of 10 bar.

If the gas mixture now changes from the lean to the rich range again, so this means that at a transition -2 from a partial pressure of 10 to one Partial pressure -4 of 10 4 bar a lot more oxygen molecules are transported have to be bar as in the transition from 10 15 -4 to 10 4, that now for the transport this many oxygen molecules from the covered part of the electrode Much more time is required for the uncovered part, in other words means that the transition of the measuring gas from lean to rich is understood much more slowly than this is the case in the reverse direction. This comes in the curve 8 in Figure 2 clearly expresses, where it is shown that the voltage of the counter electrode, starting from about 100 mV, for example, initially increases very slowly by only later, after a delayed steep rise, the limit voltage of the fat To approach measuring gas.

It is thus clearly shown that the response time of this electrode is asymmetrical in terms of repeated changes between fat and lean.

The functioning of the lambda probe according to the invention is shown in FIG made clear. Figure 3a shows the time course of the lambda value, which is determined by the Lambda end itself is effected in cooperation with a control device. figure 3b shows the voltage of the counter electrode described - measured z. B. against a Air reference - with the lambda curve corresponding to Figure 3a. These curves were derived from those of FIG. 2 for several successively occurring lambda changes. FIG. 3c shows the voltage of a conventional lambda probe electrode - measured against Air reference -. This electrode serves as a measuring electrode. Finally, Figure 3d shows the voltage of the measuring electrode against the counter electrode - the difference between the curves 3c and 3b -, thus the voltage that is applied to a sensor according to the invention without Air reference is measured. You can see that after a few transients the probe voltage exactly follows the lambda change.

The mechanism of a bold reference will now be based on FIGS to be discribed. In this case, too, the probe consists of the solid electrolyte 1, the measuring electrode 2 and the conductor track 3. Also the counter electrode 4 and the adjoining conductor track 5 corresponds to the illustration in FIG. 1. In FIG Case of this fat reference, in which the response time of the counter electrode at the transition of the measuring gas from lean to rich is shorter than the response time when transitioning from fat to lean, the entire electrode 4 is now covered with a diffusion-inhibiting layer covered, the pores of which have diameters that are small compared to the mean free one Path length of the gas molecules. The production of such porous layers is in the DE-OS 29 45 020 described. The transition from rich to lean corresponds to a higher one Supply of oxygen in the gas to be measured, but the diffusion-inhibiting layer 9 is like this designed that the oxygen molecules only slowly through the layer 9 through the electrode 4 can reach. This is shown in FIG. 5 with the aid of curve 11. If the gas to be measured changes from lean to rich again, the first prevails at the Electrode 14 has an oxygen partial pressure of about 10 bar, but this is what matters here the hydrogen present in the measuring gas plays an important role, due to its very much smaller diffusion coefficient very quickly due to the diffusion-inhibiting Layer 9 can pass through to the electrode 4 and here with the existing Oxygen is combined into water, which leads to the fat potential being attached to it Counter electrode adjusts very quickly. This is again in Figure 5 on the curve 10 clearly seen.

The voltage of a sensor according to the invention with a fat reference can in the same way by forming the difference be obtained like it described above in the lean reference. By reversing the polarity, a sensor signal is obtained this with signals from probes with a LuStreference as well as with signals from probes is compatible with the inventive lean reference.

It was emphasized above that such electrodes with asymmetrical Response times can only serve as a reference if regulation is provided that brings about a constant change between fat and lean. The control frequency is around one Hz. Another prerequisite for using this method is that the slow process taking place at the counter electrode at least lasts about as long as a normal oscillation. This has to be done in the coordination between Regulation and design of the counter electrode are observed.

Requires the process that takes place slowly on the counter electrode less time than a normal oscillation, the entire system takes too long to settle.

To get the control oscillations in mm when starting an engine: £.

It is advantageous if the lambda probe for example, on the side of the measuring electrode additionally carries a heater, since the functionality of the solid electrolyte only at a certain threshold temperature, which is between 300 and 14,000 depending on the solid electrolyte material.

Since the engines start rich in most cases, it is advantageous to use a fat reference in the method according to the invention, as it was described with reference to Figures 14 and 5, since only in this Cases after a very short time the reference potential of the counter electrode is available It is, in principle, also possible to use a lean reference when starting in rich to use, in this case only more time is required until the lambda probe is in an operationally favorable condition, - blank page -

Claims (10)

Claims 1. A method for generating a reference potential potentiometric lambda probes, in which the measuring electrode and counter-electrode are connected to the exhaust gas are exposed and have a scheme that constantly alternates between brings about fat and lean at a constant frequency, characterized in that that the counter electrode is designed such that the response and dead time when The transition of the measuring gas from rich to lean deviates from the response and dead time when the measuring gas changes from lean to rich (asymmetrical response times). 2. The method according to claim 1, characterized in that the response and dead time in the transition of the measuring gas from rich to lean is shorter than the response and Dead time in the transition from lean to rich (lean reference). 3. The method according to claim 1, characterized in that the counter electrode is partially covered gas-tight. 4 '. Method according to Claim 3, characterized in that the counter-electrode is partially covered with a glaze. 5. The method according to claim 3 or 4, characterized in that the Counter electrode is covered gas-tight to 1/3 to 2/3 of the entire area. 6. The method according to claim 1, characterized in that the response and dead time in the transition of the measurement gas from lean to rich is shorter than the response and Dead time in the transition from rich to lean (fat reference). 7. The method according to claim 6, characterized in that the counter electrode is covered with a diffusion-inhibiting layer that prevents the diffusion of oxygen inhibits more than the diffusion of hydrogen. 8. The method according to claim 7, characterized in that the counter electrode is covered with a diffusion-inhibiting layer which has pores, the diameter of which are small compared to the mean free path of the oxygen molecules. 9. The method according to claim 1, characterized in that immediately after commissioning the lambda probe, a voltage between the measuring and the counter electrode is applied to generate a pump current. 10. The method according to claim 7 or 8, characterized in that a layer of one between the electrode and the diffusion-inhibiting layer Metal / metal oxide mixture is arranged.