DE3104986C2 - - Google Patents

Description

State of the art

The invention is based on a polarographic measurement according to the genus of the main claim. With such polarographic sensors, according to the diffusion limit current principle work, this diffusion limit current at a constant, on the two electrodes of the measuring sensor measured voltage. This stream is in a lean during combustion processes provided exhaust gas from the oxygen concentration for so long depending on how the gas diffuses to the cathode The speed of the reaction taking place is determined.

Such polarogra has already been proposed build phical sensors in such a way that both Anode and cathode exposed to the gas to be measured are. Such sensors are simple in construction and are therefore suitable for production in large quantities, but they have the disadvantage that their display is due the temperature dependence of the internal resistance of the Solid electrolytes, due to the signs of aging Electrodes as well as due to the dependence of the implementations changes from ambient pressure. On the one hand, this leads to a Time drift which requires re-calibration from time to time when it comes to accurate measurements of oxygen levels on the other hand, it becomes necessary under these conditions  be, the temperature and pressure dependence on any Way to take into account in the measurement results.

Advantages of the invention

The polarographic sensor according to the invention with the characteristic features of the main claim has demge compared to the advantage that the temperature and time drift is compensated so that the display is independent of the Change in the internal resistance of the solid electrolyte with the temperature and also the signs of aging the electrodes can occur. Therefore it is repeated Re-calibration of such sensors is no longer necessary.

By the measures listed in the subclaims advantageous developments and improvements in Main claim specified sensor possible. Especially It is advantageous if the cathodes of both systems have are connected to a channel whose diameter is large compared to the mean free path of the gas molecules, see above that the gas molecules through the so-called gas phase diffusion get to the cathodes, which means that the measurement results nise become independent of the absolute pressure of the surrounding Gases. A further advantageous embodiment can be achieved if at least one of the anodes is connected to the outside atmosphere, because this also means that the Area clear measurement results can be achieved. Finally, it is advantageous if the solid electrolyte body has the shape of a plate, which in its Dimensions and thus as small as possible in volume so that it is everywhere, especially when the temperature changes has approximately the same temperature.

In a second embodiment, the measuring element is used instead of the diffusion channel a fine-porous layer over the cathode upset. The pore diameter is smaller than on average  the mean free path of the gas molecules that pass through it diffuse. The measurement of the oxygen partial pressure depends then also from the absolute pressure. To avoid this influence switch, is also a porous over the reference electrode Layer applied. The connection with the atmosphere about a channel without diffusion inhibition remains. On in this way the absolute pressure influence is compensated, whereby it is assumed that the sample gas and reference gas atmosphere subject to the same pressure.

drawing

Two embodiments of the invention are in the drawing shown and in the following description explained. It shows

Fig. 1 is a perspective view of a first embodiment,

Fig. 2 shows a section along the line AA of FIG. 1 and

Fig. 3 shows another embodiment of the invention.

Description of the embodiments

The sensor according to Fig. 1 consists of a solid electrolyte plate 1 of for example 50 mm x 8 mm x 1 mm made of stabilized zirconia. As shown in FIG. 2, this plate carries four electrodes 2, 3, 4 and 5 , which consist either of platinum or of a mixture of platinum and stabilized zirconium dioxide, this zirconium dioxide accounting for approximately 40% by volume. The cell consisting of the solid electrolyte 1 and the electrodes 2 and 3 measures the reference gas, while the cell consisting of the electrolyte 1 and the electrodes 4 and 5 measures the gas with the unknown oxygen content. For this purpose, each of the two cells is connected to a DC voltage source of a few volts such that electrodes 2 and 4 are connected as cathodes and electrodes 3 and 5 as anodes. The current flowing there can be measured in each of these circuits. While in this embodiment the anodes 3 and 5 are exposed to the measuring gas - they can only be protected by a porous layer (not shown in the figure) - the cathodes are covered with a gas-tight hollow roof 6 and 7 , respectively, to which channels 8 and 9 Connect. Channel 8 represents the channel for the reference gas air, which comes from the direction indicated by arrow 10 , while channel 9 represents the measurement gas channel, the measurement gas coming from the direction of arrow 11 . The channels 8 and 9 have a height of about 20 microns and a width of about 0.2 mm. They serve as defined diffusion resistances for the oxygen molecules of the sample gas or atmospheric oxygen and are necessary so that the sensor can work in the current diffusion limit range at all. The manufacture of the hollow roofs labeled 6 and 7 and the channels labeled 8 and 9 is described in detail in German Patent Application P 29 28 496.6.

Since a constant oxygen partial pressure of 20.8% oxygen is measured with the cell 1, 2, 3 , the change in the limit current measured with this cell depends solely on the temperature of the cell, while the change in the measurement gas cell 1, 4, 5 measured limit current both from the temperature and from the Sauer in this way compensated for the temperature effect, so that the signal obtained in this way depends only on the oxygen partial pressure of the sample gas. The compensation for the aging drift results from the fact that all four electrodes 2, 3, 4 and 5 were produced in the same way and therefore also age in the same way, since they are always exposed to practically the same temperature. The measurement results are also independent of the absolute pressure of the environment, so that a height correction is not necessary for precise measurements.

However, the measurement results of a sensor with a fine-porous layer are dependent on the absolute pressure of the environment, so that in this case a height correction must be taken into account in the measurement results for precise measurements. Fig. 3 shows an embodiment in which this dependence of the measurement results on the absolute pressure can be compensated for a sensor with a fine porous layer. For this purpose, it is only necessary to apply porous ceramic layers over both cathodes 2 and 4 , in which the diameter of the pores is small compared to the mean free path of the gas molecules. Such a layer leads to the so-called Knudsen diffusion, in which the amount of gas diffusing depends on the one hand on the temperature, but on the other hand depends on the prevailing pressure. In contrast, diffusion through porous layers with larger pores is independent of the prevailing absolute pressure. Such a porous layer, which enables Knudsen diffusion, must have pores with a diameter of approximately 0.1 μm. Such porous layers can be achieved by using a paste made of a very finely divided ceramic material, e.g. B. from zirconium dioxide or from aluminum oxide, over the electrodes 2 and 4 prints and then, together with the other layers, sinters. The size of the pores depends on the suitable choice of the grain size of the ceramic material and must be determined for each material by appropriate tests. Such a sensor is shown in FIG. 3, the electrode arrangement again corresponding to that in FIG. 2 and only the end state of the top of such a sensor being shown in FIG. 3. On the solid electrolyte plate 1 there are in turn the electrodes 2, 3, 4 and 5 according to FIG. 2, but which are not visible in FIG. 3. Above the electrodes 2 and 4 are the above-mentioned fine-pored layers, of which only the one exposed to the measurement gas and designated by 12 in FIG. 3 is visible. The fine-pored layer belonging to Elektro de 2 is again covered with a hollow roof 13 , to which an air duct 14 closes, but this time it is dimensioned such that it does not act as a diffusion barrier for the atmospheric oxygen. This channel is approximately 1.0 mm wide and 50 µm high. The circuit is again the same as that indicated above using the example of FIG. 1.

The exemplary embodiments described so far are outstandingly suitable for measurement in the lean range and also yield clear measurement results here. However, if one also measures with this sensor in the free range, it becomes apparent that the diffusion limit current, coming from larger lambda, decays to 0 at λ = 1, but increases again as the lambda decreases, probably caused by oxidation and reduction processes at the electrodes , so that in this case there are two lambda values for each measured value of the diffusion limit current and the measurement is therefore not clear, ie one cannot clearly determine whether one is in the lean or in the rich range. The reason for this is that the anodes 3 and 5 are exposed to the exhaust gas, so that the reactions just mentioned can take place there. If you now ensure that at least one of the anodes 3 and 5 is better but both are in contact with the outside air serving as the reference gas, the current flows during the transition from the lean to the rich region, ie at λ = 1 in the opposite direction thus gets a negative current value for λ <1, so that the measurement results become clear again because only one lambda value can be assigned to each value of the diffusion limit current. Such a connection of the anodes 3 and / or 5 can be reached in a simple manner in that, as shown in Fig. 1 at the points 6 and 8 via this hollow roofs and subsequently installing channels.

For the electrical connection of the electrodes proceeding from conductor tracks to suitable points on the fixed electrical system led to the application of voltage to the cells in to ensure as simple as possible. The conductor tracks are preferably made of Pt or other temperature resistant other metals. These conductor tracks are preferably through a Isolation layer separated from the electrolyte and by a Glaze covered to avoid the traces in some form on the reactions that are on the electrodes run, participate and thereby falsify the measurement results.

Claims (9)

1. Polarographic sensor for determining the oxygen content in gases, which works according to the diffusion limit current principle, with an oxygen ion conductive solid electrolyte body, which carries an anode and a cathode exposed to a measuring gas, to which a constant voltage can be applied, the cathode passing through a layer having pores or channels is covered, characterized in that the same solid electrolyte body ( 1 ) carries a second system consisting of anode ( 2 ) and cathode ( 3 ), the cathode ( 3 ) of which is likewise through a pore or channel having layer ( 6 ) is covered, a reference gas with constant oxygen partial pressure is exposed. 2. Sensor according to claim 1, characterized in that the solid electrolyte body ( 1 ) has the shape of a plate. 3. Sensor according to claim 1 or 2, characterized in that the solid electrolyte body ( 1 ) consists of stabilized zirconium dioxide and the electrodes ( 2, 3, 4, 5 ) made of platinum or a mixture of platinum and stabilized zirconium dioxide. 4. Sensor according to one of claims 1-3, characterized in that the cathodes ( 2, 4 ) of both systems via channels acting as diffusion barriers ( 8, 9 ) are connected to the measuring or reference gas. 5. Sensor according to one of claims 1-3, characterized in that the cathodes ( 2, 4 ) of both systems are covered with a porous ceramic layer ( 12 ), in which the diameter of the pores is small compared to the mean free path of the gas molecules (Knudsen diffusion). 6. Sensor according to claim 5, characterized in that the pores in the porous ceramic layer ( 12 ) have a diameter of the order of <0.1 microns. 7. Sensor according to one of claims 4 or 5, characterized in that the anodes ( 3, 5 7) are exposed to the measuring gas. 8. Sensor according to one of claims 4 or 5, characterized in that at least one of the anodes ( 3, 5 ) is in communication with the outside atmosphere. 9. Sensor according to claim 8, characterized in that the one related to the outside atmosphere Anode is covered with a hollow roof to which one channel related to the outside atmosphere connects.