DE10007010C2 - Sensor unit for determining the exhaust gas recirculation rate of an internal combustion engine - Google Patents

Description

The invention relates to a device for determining the Exhaust gas recirculation rate of an internal combustion engine according to the preamble of claim 1

The main emitters of nitrogen oxides (NOx) in the industrial state These include transport, fossil-fueled power plants and industrial plants lay. While the power plant and industrial emissions always continue to decline, the proportion of traffic is increasing the foreground.

The NOx emissions of gasoline-powered gasoline engines can by the operation at λ = 1 and after engine exhaust gas purification by means of a three-way catalyst can be drastically reduced. Prin zipbedingt this possibility exists in the mixture controlled Diesel engine, which is operated stoichiometrically, not. Due to the high oxygen content in the exhaust gas is still today No catalyst realized that reduces NOx emissions without adding of reducing agents (possibly also in the form of rich exhaust gas), i. A. hydrocarbons or ammonia-forming compounds, can reduce. The same applies to lean-burned Ottomoto ren.

Another long known option, NOx emissions lower, consists in the exhaust gas recirculation (EGR). By Zumi From exhaust gases to fresh air before combustion is in the special reduces the temperature-dependent NOx emission. Übli cherweise is by an exhaust gas recirculation line from a Exhaust pipe of the internal combustion engine exhaust gas in an inlet line recycled. The recirculation rate of the exhaust gas, d. H. the Amount of proportionate to the fresh air flow in the inlet pipe  admixed exhaust gas flow in relation to the combustion air quantity, is adjusted by a controller unit to match be control point-dependent predetermined setpoint values. An increase the exhaust gas recirculation rate with the intention of another Reduction of NOx emission becomes an operating point dependent different border set, namely by the above this permissible recirculation rate increasing soot or particles emissions, fuel consumption and deterioration sion of the smoothness of the internal combustion engine.

The implementation of a regulation of the exhaust gas recirculation rate he calls for the ongoing recording of the respective repatriation conditions in the operation of the internal combustion engine. Simple tax method of recirculated exhaust gas amount, such as by be operating point-dependent control of the exhaust gas recirculation valve adjustable opening stroke, the exhaust emissions can only unbe lower peacefully, since the repatriation rate in the respective Be operating point significantly below the optimum setpoint must, in order to do this without feedback of the exhaust gas flow otherwise Fige violating the soot limit and the corresponding high emis avoidions.

From EP 0 574 614 A1 a method for controlling the Ab gas recirculation rate, which is used to determine the actual Value of the recirculated exhaust gas mass flow to the pressure drop a Venturi nozzle in the exhaust gas recirculation passage measures and off the pressure difference determines the flow. However, since the Backflow of the exhaust gas through the exhaust gas recirculation line from Pressure gradient between exhaust pipe and inlet pipe of Internal combustion engine is driven, reduces the pressure loss at the Venturi nozzle that is available for recirculation Pressure gradient. Here, the possible exhaust gas recirculation rate reduced and it can burn in many operating points engine is not the optimal reduction of exhaust emissions be achieved. In addition, the provision of Ab Gas flow through the exhaust gas recirculation line over the Measurement of the differential pressure very inaccurate, as accurate measurements  presupposes laminar flow conditions at the Venturi nozzle zen, which in the exhaust of internal combustion engines practically not occurrence. The more or less turbulent Ab occurring Gas flows of different internal combustion engines, esp dere in the operation of supercharged internal combustion engines, verhin an effective regulation of the repatriation rate with the be knew procedures.

DE 43 37 313 C1 proposes to detect the recirculated Ab gas quantity before, the absolute pressure and the temperature in the exhaust gas line of the internal combustion engine to measure. To determine the Return rate is measured as the static pressure also the back pressure of the exhaust gas needed. With the known Ver driving is however an accurate determination of the return rate, which is indispensable for optimum regulation, hardly possible Lich, as the required temperature and pressure sensors of very high exhaust gas temperatures are applied. Over there From the high carbon black content of the exhaust gas leads to a zuneh clogging of the probes as the loading progresses operating time of the internal combustion engine, whereby the measurement results increasingly inaccurate and thus ultimately higher Abga be caused.

DE 197 34 494 C1, on the other hand, proposes determining the recirculation rate with the aid of two oxygen sensors, which are arranged before and after the confluence of the exhaust gas recirculation line into the inlet line. According to the equation given in DE 197 34 494 C1

the return rate can be determined. Here, R is the gas recirculation rate, and [O ₂ ] is the oxygen concentration, where in the indices vM before engine (= after the mouth of the exhaust gas recirculation channel in the inlet line) and R recirculated exhaust gas (= before the confluence of the exhaust gas recirculation line in the inlet). These definitions of vM and R are retained in the present application. The factor 0.23 indicates the mass fraction of oxygen in the ambient air.

Although with this method, the exhaust gas recirculation rate can be true be, there are disadvantages. On the one hand, the currently existing, working on the amperometric principle and working in the entire lean oxygen sensors at λ <2 (ie [O ₂ ] <10%) are very inaccurate, on the other hand, as easily from Eq. (1) it can be seen that, especially with large λ values, the accuracy can be high, in order to be able to determine, in particular, sufficiently small return rates. This is clear from the following example: At a recirculation rate of 10% and a λ = 2 (10% oxygen), [O ₂ ] _vM = 21.7%. A measurement error of the oxygen concentration before Mo tor by only 1% of the measured value leads to an error in the return rate of 16.7%.

Another disadvantage is that two sensors to two different which installation locations must be attached, resulting in additional Costs for sensors, installation and construction leads. In addition, occurs an increased risk of default.

Also two sensors at two different locations requires the possibility proposed in DE 197 28 353 C1 to regulate the 3-way mixer and thus the exhaust gas recirculation rate as a function of the CO ₂ concentrations in the charge air line and from the gas return line.

It is the object of this invention to provide a device with the accurate determination of the exhaust gas recirculation rate zuver can be achieved casually and inexpensively.

This object is achieved with the device according to claim 1 solved. Advantageous embodiments are the subject of Unteran claims.  

The device according to the invention is on the one hand with the Ab gas atmosphere within the exhaust gas recirculation line beauf beatable, and on the other hand with the within the inlet pipe the internal combustion engine after the confluence of the exhaust gas recirculation line existing atmosphere from exhaust and fresh air beauf beatable. The two are beaufschla the device gas atmospheres kept separate by means of separate holding means. The Sen Soreinheit the device may consist of one or more Einzelelsen insist. In addition, an additional ambient air rec be present.

The invention will be described with reference to embodiments Be access to drawings. Show it:

Fig. 1 shows the basic structure of an exhaust gas recirculation system, from which the invention proceeds;

Fig. 2 shows an embodiment according to the invention in a schematic representation;

Fig. 3 is an enlarged detail of Fig. 2;

Figures 4, 5 embodiments of the invention using an electrochemical cell with selectively ion-conducting membrane.

Fig. 6, 7 embodiments according to the invention using an electrochemical cell with oxygen ion-selective membrane ver;

Fig. 8 is an embodiment of the invention using two resistive he oxygen sensors;

FIG. 9 shows an embodiment according to the invention using two amperometric oxygen sensors; FIG.

Figure 10 is an embodiment of the present invention using an amperometric oxygen sensor and an elec trochemical cell with a selectively ion-conducting membrane.

FIG. 11 is an embodiment of the invention employing a resistive oxygen sensor and a elektrochemi specific cell with a selectively ion-conducting Mem bran;

Fig. 12, 13 an embodiment of the invention using two he amperometric NOx sensors;

FIG. 14 is an embodiment of the invention utilizing two gas sensors it in a schematic representation;

Fig. 15-18 embodiments of the invention with different arrangement of the sensor unit within the exhaust gas recirculation system.

Fig. 1 outlines the necessary for an exhaust gas recirculation system notwendi components. The exhaust gas A is supplied via a valve or a controlled flap V a cooler K and cooled with the fresh air required for the combustion F mixed. The recirculated exhaust gas within the exhaust gas recirculation line is designated R. The mixed with cooled exhaust R fresh air F is designated vM. Cooling is not essential, but increases NOx reduction.

Fig. 2 shows a first embodiment according to the invention in a schematic representation. In this case, each of the exhaust gas recirculation line and the inlet line stub lines are attached. Instead of stub lines, other, structurally advantageous embodiments, as they are for. As shown in FIGS. 15 to 18 are used. The stub lines each lead to the same sensor unit Sb, which is thus in contact with the recirculated exhaust gas R on one side and with the gas mixture vM on the other side. It is important that the sensor unit Sb is in contact with both gas atmospheres and that both gas atmospheres vM, R are separated from one another. In Fig. 3 the dashed line cut is shown once again enlarged. It can be seen how the separate gas atmospheres R and vM act on the Sen soreinheit Sb from different sides. The Sen soreinheit Sb is integrated into the partition, which separates the two Gasatmosphä ren R and vM from each other, or even forms a part of this partition. The two gas atmospheres R and vM are thus separated vonein other by means of the sensor unit Sb itself.

For the mass flows applies:

The return rate R is defined

For concentration of any gas g applies

Here, a _{g is} the conversion factor of volume percent in mass percent. a _g is slightly different for each gas, but can be approximately seen as independent of the operating point of the engine.

In the event that g denotes a gas which is formed during the combustion of fuel and which is present in the ambient air in virtually no or substantially lower concentration than in the exhaust gas, the term [g] _F × _F can be neglected and receives:

Gases for which the Glg. (5) and (6), z. For example:
CO ₂ , NO, NO ₂ , N ₂ O, hydrocarbons, SO ₂ , SO ₃ , H ₂ or even What steam, if the ambient humidity compared to the originating from the United combustion moisture can be neglected.

In the case that the gas g is present in the ambient air, ie that the term [g] _F × _F can not be neglected, the following applies:

The concentration [g] _{F of} the gas g in the intake pipe, before the confluence of the exhaust gas recirculation line, ie in the fresh air, is generally identical to the concentration [g] _L in the ambient air outside the exhaust gas recirculation system. Therefore, as needed, [g] _{F can be} replaced by [g] _L.

On the basis of the above derivations, below several concrete embodiments of the invention Sensor unit explained. It can be one or more individuals include sensors.

1. selective ion conductor / electrochemical cell for selective to one in the ambient air not or only negligible sigbarer concentration occurring gas

In the simplest embodiment, the sensor unit consists of a selectively ion-conducting membrane, which is provided with suitable, possibly porous, electrical electrodes to which supply lines are attached. The membrane is brought to a temperature where ionic conduction occurs. The membrane should be selectively g on a in the ambient air not or only in ver negligible concentration occurring gas. For se lectively ion-conducting membranes, the Nernst equation applies, which describes the resulting electromotive force (referred to here as U) between the two electrodes as a logarithmic ratio of the partial pressures of the gas g on both sides. If the total pressures in both gas chambers are the same, this law also applies to the gas concentrations:

If the pressures differ from each other, the result must still be

Getting corrected. In Glg. (8) c stands for a constant that depends only on natural constants and on the valency of the membrane's mobile ion. p _vM and p _R denote the total pressures in the respective gas spaces.

Used in Glg. (6) gives the simple connection:

It does not matter which ion the membrane ions is selective, as long as it is ensured that no disturbing share can be done by sucked air, ie it must Eq. (6) apply. Membranes that can conduct both one and several ion species can also be taken into account under this condition. For example, a membrane which is both per-ion conducting and H ₃ O ⁺ -conductive may also be used, so that cross-sensitivities do not matter. It is advisable to heat the membrane and to provide it with a Temperatursen sor. Then, either can be regulated to a constant Ar beitemperatur, and / or it can measure the tempera ture and closed it together with the electromotive force to the return rate. An example of a suitable sensor for this application can be found in DE 197 14 364 A1, where a potentiometric sensor is described with egg ner NO-conducting membrane. The described bene sensor for determining the exhaust gas recirculation rate by means of an ion-selective membrane should be referred to here as a sensor of the first kind. A schematic of such a sensor is shown in FIG . There, M denotes the membrane and E1 a preferably porous electrode. Heaters and devices required for tempera turefassung and temperature control were not outlined for clarity. Also orders to lead out the electromotive force from the sensor element were the sake of clarity weggelas sen.

In another embodiment of the invention, which is to be understood here as Sen sor second type, an ion-conducting membrane of a non occurring in the gas ion z. B. Li ⁺ , Na ⁺ , K ⁺ , H ⁺ , or even a divalent ion z. As Ca ²⁺ or Mg ²⁺ or even a polyvalent ion can be used. Then, however, acting as a potential generator, preferably formed as a layer material in which this ion just happens if upstream or downstream. In Fig. 5, this embodiment is the example of a Na ⁺ -β "-Al ₂ O ₃ membrane, that illustrates a sodium ion conductor. The membrane M is be made of Na ⁺ -β" -Al ₂ O _3, to which on both sides Na ₂ CO _{3 was applied} as potential former Pb. Two, each with a line provided preferably porous electrodes El com complete the basic structure. There is thus obtained an electrochemical cell having the following appearance:
Electrode | Na ₂ CO ₃ | Na-β "-Al ₂ O ₃ | Na ₂ CO | Electrode

Due to the different CO ₂ activity on both sides of the electrochemical cell, an electromotive force is formed, which is proportional to the logarithm of CO ₂ - concentrations. According to Eq. (8) can thus be determined the Rückfüh rate. The simplifications in the illustration mentioned in connection with FIG. 4 also apply to FIG. 5.

As a further embodiment of the potential generator can be combined with the elec trode, z. Example, in that the electrode mate rial with the mobile ion in the membrane is identical. This embodiment is to be understood as a third type sensor here. An Ag-β "-Al ₂ O ₃ membrane which has been contacted with silver may be mentioned as an example: Even then, owing to the reaction of the silver electrode with CO ₂ or NO x in the gas to form the corresponding silver salt, a different chemical potential can build up, which can be measured as electromotive force.

It should be underlined once again that o. G. from only as examples, both ways visibly the choice of ions as well as in terms of off Choice of potential formers and electrodes. It can too Mixed forms of sensors first and second, first and third and second and third kind are realized.

For sensors of the first to third type, there are some significant advantages over the sensors of the prior art mentioned in the introduction to the description:
No reference atmosphere is needed, unlike a conventional λ probe. Both sides of the membrane can easily be kept at the same temperature. Another particular advantage proves that with smaller Rückführungsra th the electromotive force is greater in magnitude, and that the relative error

is proportional to the logarithm of the return rate

how to easily turn off. (9) can calculate. That is, the relative error at a Return rate of 1% is only worse by a factor of 3.8 than at a repatriation rate of 30%. The with decreasing Return rate increasing signal and only underproportion nal increased relative errors at low recycle rates ma chen this type of determination of the exhaust gas recirculation rate FITS that's interesting.

Another advantage is the unneeded selectivity the sensors to others in the ambient air not or only in negligible concentration of occurring gas components. For example, one sensor can sense several gas components be. Since these are on both sides of the membrane (gasat mospheres vM and R) according to the return rate,  the measuring signal is not due to varying gas together be disturbed.

2. selective ion conductor / electrochemical cell with acid stoffionenselektiver membrane

Embodiments with a suitable arrangement of oxygen-sensitive membranes are also applicable. If you put in Glg. (7) for the gas type oxygen on, we obtain:

Substituting now between the gas-separated spaces vM and R an electrode provided, oxygen ion-conducting membrane (ty typically with yttrium stabilized zirconia, YSZ), which has the electromotive force U _{vM / R} , we obtain:

This means that, due to the oxygen present in the ambient air, the term [O ₂ ] _F / [O ₂ ] _{R has to be} taken into account, where for [O ₂ ] _F the concentration of oxygen in the air can be used, ie O ₂ ] _F ≈ 0.21.

Some embodiments according to the invention now offer themselves how, despite this additional term, the return rate can be determined with a single sensor unit. So z. B. a second additional membrane in the sensor unit are installed so that even a measurement against ambient air (index L) is possible. FIG. 6 and FIG. 7 show inventive arrangements. Heaters and devices required for temperature detection and temperature control were the sake of clarity not shown. It can be seen in FIG. 6 how, with two membranes M1, M2 in a single sensor unit, the electromotive forces U _{vM / R} on the membrane M1 and U _{F / R} on the membrane M2 can be determined. E1 denotes the electric the. After Glg. (12) the return rate can be calculated from this. But it is also possible to come trainees with only one membrane by, as shown schematically in Fig. 7, three electrodes E1 are applied to a membrane M, which are arranged so that a common electrode in the gas space R an elec trode in Gas space vM and an electrode in the gas space L, ie facing in the ambient air. The return rate R he then pays off as follows:

Since in such an embodiment with only one membrane gets along, fall over other embodiments and against over the prior art, where two separate in different where oxygen sensors located in gas chambers are needed, many manufacturing steps away, resulting in a very cost effective and space-saving sensor unit leads. Also the accuracy is increased because the parameter T (temperature) in Eq. (13) at is equal to all three terms. Thus, a possibly existing This temperature error only once.

3. resistive oxygen sensors

In this embodiment, no ion-conducting membrane be needed. A sensor (RSS1, Fig. 8) is acted upon by the exhaust gas atmosphere within the exhaust gas recirculation line and the other sensor (RSS2, Fig. 8) with the present within the inlet pipe after the confluence of the exhaust gas recirculation line gas atmosphere from exhaust gas and fresh air acted upon. The resistive oxygen sensors do not require a reference atmosphere. It can Kings z. B. two oxygen sensors in the separation layer, which separates the two gasatamospheres, are integrated. Particularly advantageously, the two resistive oxygen sensors can be applied to a single heated substrate.

Resistive oxygen sensors usually have a characteristic according to Eq. (14) (see DE 197 44 316 A1)

W = W ₀ × pO ₂ ^m (14)

Here, the symbol W was chosen for the electrical resistance in order to avoid confusion with the return rate. According to Eq. (14) can be concluded from the knowledge of the two measured Wi resistances on the oxygen content in both gas chambers ge and with the aid of Eq. (11) the repatriation rate is calculated. The embodiment according to the invention of two sensors integrated in a sensor unit has advantages over the concept of two sensors mounted at different locations. First, in contrast to the commercially available oxygen sensor according to the limiting current principle, the error

and thus independent of the oxygen content. Secondly, resistive oxygen sensors can be used to obtain sensor units that are substantially less expensive than amperometric oxygen sensors (as an exemplary embodiment for an amperometric oxygen sensor, see, for example, WO 95/25276), which also take up less installation space due to their miniaturization. An example of this is shown in FIG. 8. There are even possibilities for configuring the resistance materials for the resistive oxygen sensors such that they are no longer temperature-dependent (DE 197 44 316 A1).

A possible structure of such a sensor unit according to the invention in layering technique is shown in Fig. 8: On a sub strate Su, which separates the two gas chambers, a heating and Tempe raturmeßwiderstandsschicht He is applied to an Iso lierschicht Is follows. A resistive oxygen-sensitive resistive _layer , whose resistances W _R and W _{vM are measured} at the electrodes E1 and is then followed by the Eqs. On both sides facing the gas chambers R and vM, follows in each case. (14) and (11) can be evaluated.

4. amperometric oxygen sensors

According to the invention, the sensor unit can also be realized with two amperometric trical oxygen sensors (ASS1, ASS2, FIG. 9). These can each be sensors according to the single-chamber (also single-cell), two-chamber (also two-cell) or multi-chamber principle (also called multi-cell principle) constructed. In this case, both solutions can be realized that provide a connection to the outside air, as well as structurally simplest solutions as outlined in Fig. 9. There are applied to a provided with electrodes E1 membrane M to each gas space R, vM toward at least one Weil diffusion barrier Db and the limiting current principle, such as. As described in [1] applied. The Ge accuracy is compared to the sensor according to DE 197 34 494 C1 increased, since the temperature error is received only once, and since possible aging effects symmetrically auftre th on both sides. Heating and temperature control for the temperature and temperature control devices needed for clarity were sake half again not shown.

5. amperometric NOx sensors

According to the invention, two amperometric NOx sensors (ANS1, ANS2 in Fig. 12) may also be present in the sensor element. This can z. B. each sensor according to the two-chamber principle. In this case, both solutions can be realized, the one - possibly common, connection to the outside air vorse hen, as well as solutions that - as outlined in Fig. 13 - to use as a reference the other gas space. One possibility of a sensor with a common reference to the outside air is sketched in FIG. 12. As in the previous drawings, the presentation of heating, Elek trodenzuführung and housing was omitted for clarity. On the membrane M, consisting of an oxygen ion conductor such. B. YSZ an electrode pair E11 is applied. By applying a pumping voltage between the two electrodes, which drives a pumping current, the chamber K1 is freed of oxygen. Only through a diffusion opening D1 is K1 in communication with the gas space R. The oxygen partial pressure in K1 is measured by means of the electrodes E12. However, the voltage applied to E11 can also be used as a measure of the oxygen partial pressure in K1. The oxygen-depleted gas reaches the chamber K2 via the diffusion opening D2. There takes place at an applied pump voltage to the - if possible for a NOx decomposition or H ₂ O decomposition active - electrodes E13 a transport of oxygen ions in the outer space L instead, which is proportional to the NOx content in the gas space R. The pumping current is then the measuring signal. An identical arrangement can be introduced for the gas chamber vM, as shown in Fig. 12 also shown. From the two pumping currents can then be closed directly ge to the exhaust gas recirculation rate. A typical arrangement of such a sen soreinheit within the exhaust gas recirculation system could then look as shown in Fig. 16 or 18.

Suitable embodiments for the sensor with reference NO.sub.1, NO.sub.x2 shown in FIG. 13 are to be found in the following literature and the appraisals of the standard of the art contained therein: DE 198 27 927 A1, EP 0 867 715 A1, EP 0 863 399 A2, EP 0 862 056 A1, EP 0 859 232 A2 or EP 0 769 694 A1.

With this genus, embodiments are useful Additional information about the determination of exhaust gas recirculation rate of increase. So z. B. also the NOx content in the Ab Gas determines and thus the effectiveness of the exhaust gas recirculation he be averaged. Functionally, such NOx sensors deliver also the λ-value in the gas atmospheres vM and R (ie in the exhaust gas), and thus provide important additional information necessary for the Mo Gate control can be used.  

6. other gas sensors

Another possibility according to the invention is the arrangement of two other gas sensors, which are selective to a component present in the exhaust gas, in the sensor unit. In Fig. 14, these sensors are denoted by S1 and S2 and integrated within the Sen soreinheit Sb. The two sensors can selbstver of course along the partition wall of the two gas chambers R, vM be moved spatially Lich each other. Commercially available are H ₂ , HC, NOx, CO or CO ₂ sensors. But even sensors for other in the ambient air only in negligible Kon concentration existing exhaust gas components are conceivable. The evaluation then takes place according to Glg. (6).

As materials for such sensors are often semiconducting metal oxide sensors that react at certain well-defined temperatures Tempe on certain gas components very selectively with a change in resistance used. Usually they are produced in layering techniques. Therefore, as a possible Liche embodiment, a structure similar to Fig. 8 offers. However, no oxygen-sensitive material is used as a sensitive layer, but rather a material sensitive to the above-mentioned components. It also makes sense to use in both gas chambers sensors made of materials that selectively change their complex electrical impedance or their electrical capacity to components occurring in the exhaust gas. As an example of such sensors, EP 0 426 989 A1 is cited.

This principle has some very advantageous properties. First, any cross-sensitivities affect other exhaust components less disturbing, as they are in both Sensors S1 and S2 appear simultaneously. The at some sensor types remaining residual cross sensitivity Oxygen is mainly at low oxygen levels. There But if it is equally pronounced at S1 and S2, it goes into the Return rate determination less strong than in the determination the absolute concentration of the exhaust gas components. In particular  at λ <2, the oxygen contents differ in the gas mospheres R and vM only so small from each other that themselves the oxygen radical cross sensitivity no longer noticeable power. Compared to the placement of the sensors at different In addition, there is the advantage of the same Sen temperature and the resulting reduction of the Error.

7. Mixed form of several sensor principles

In another genus of the invention Ausführungsfor sensor principles are combined. So z. B. by means of a membrane M ( Fig. 10) between the gas chambers vM and R, the ratio [g] _vM / [g] _{R are} determined and measured by egg ner amperometric cell ASS absolute content in one of the gas chambers. In this embodiment, one can either with a single membrane M, as shown in Fig. 10, get along, or it is used for the amperometric cell, which in turn can be constructed in the single or multi-chamber principle, a separate membrane. In Fig. 10, the heater and other for the temperature detection and temperature control Benö approved devices for the sake of clarity again are not shown. In this case, it is preferable to use, Sauerstoffio nenleiter, ie z. As the well-known YSZ to use. When sour stoffionenleiter then equal to the λ value of the exhaust gas is also measured in the gas space R, which is part of the engine control of part, as this may be possible sensors can be saved in the intake. But you also get with other io nenleitenden membranes useful additional information. So z. B. when using an NO ⁺ -selective membrane and the same NOx content in the exhaust gas are determined and thus the effectiveness of the exhaust gas recirculation can be determined.

Also, the common structure of an ion-conducting membrane, which in turn may be made of YSZ, and a resistive oxygen sensor, which may preferably be constructed in layer technologies, belongs to this category of embodiments. An exemplary embodiment of such a sensor unit is shown schematically in FIG. 11. Heating and the turefassung for temperature and temperature control required devices were again not shown for clarity. On the membrane M, which separates the two gas chambers vM and R, two electrodes E1 are applied, at which the electromotive force U _{vM / R} can be tapped. Also integrated in the sensor unit and preferably placed on the same substrate is a resistive oxygen sensor RSS, which determines the oxygen content in room R. Electrically separated by the insulator Is, which is preferably formed as a layer of the membrane M, the gas-sensitive resistance material W1, which is also preferably formed as a layer disposed. At the contacts W1 and W2, the sensor resistance W, which depends on the oxygen partial pressure, tapped. The return rate is then calculated using the Glg. (12) and (14)

Here W _{0 is} a constant that depends on the resistance material and the geometry of the resistor Wi. This form of execution has the advantage that membrane and oxygen-sensitive material can be operated at the same temperature. In particular, an embodiment using a temperatu run dependent resistive oxygen sensor, such as. As proposed in DE 197 44 316 A1, to.

8. Arrangement of the sensor unit within the exhaust gas recirculation system

The use of long stubs has the disadvantage of slow kinetics and is also costly. As an alternative, further embodiments of the invention are outlined below, which differ in the arrangement of the sensor unit within the exhaust gas recirculation system. In Fig. 15, the sensor unit Sb is a small built-in part, the z. B. can be screwed, glued or pressed, made. It directly connects the return line RL located at this point and the inlet line ELt. The constant flow of gas ensures that the sensor unit Sb on the sides R and vM constantly the correct gas concentration and no dead times as in a long spur line must be taken into account. In addition, such a component is cheaper to manufacture and install than a stub. By the contact to the medium L (ambient air) on the side also a (if required) air reference can be ensured. If the air reference is not needed, a wall of the return line RL may be identical to a wall of the inlet line ELt.

In order to improve the mixing at the measuring point on the vM side, the recirculated exhaust gas can also be blown into the inlet line ELt by means of a dip tube, as outlined in FIG. 16. It is also possible to completely integrate the sensor unit Sb into the wall of the inlet line ELt, as sketched in FIG. 17. To improve mixing, the dip tube is closed at the front. Small openings at the top and on the wall of the dip tube ensure leakage of the recirculated gas and clean mixing. In Fig. 17, the sensor unit Sb is angeord net that no air reference is available. If, as stated in some of the examples disclosed above, an air reference is needed, this could be sicherge by the sheath of the not shown here electrical supply line. This principle to create an air reference is used in the known potentiometric λ probes for use in the motor vehicle. However, it is also possible, as sketched in FIG. 18, to arrange the sensor unit Sb in such a way that both contact to the gas atmospheres R and vM and to the ambient air L exists. For this purpose, the sensor unit Sb is integrated both in the wall of the exhaust gas recirculation line RL and in the wall of the inlet line Elt.

In the application cited prior art literature

[1]: H. M. Wiedenmann, G. Hötzel, H. Neumann, J. Riegel, H. Weyl, ZrO ₂

Lambda probe for the mixture regulation in force vehicle, in: H. Schaumburg (Ed.), Sensor Applications, Teubner Verlag Stuttgart (1995) 371-399 [1].

Claims (20)

An apparatus for determining an exhaust gas recirculation rate of an internal combustion engine on the basis of gas concentration measurements in an exhaust gas atmosphere in egg ner exhaust gas recirculation line and in an exhaust fresh air atmosphere in an intake pipe of the internal combustion engine downstream of a junction of the exhaust gas recirculation line in the inlet line, with Sensor with means for measuring the respective gas concentrations and Separate holding means for separate maintenance of the exhaust gas atmosphere and the exhaust fresh air atmosphere at the respective respective measuring locations of the sensor means, characterized in that the sensor means are designed as a sensor unit (Sb), which posi on the separate holding means tioniert is that it can be acted upon by a first side with the exhaust gas atmosphere (R), and from a second side with the exhaust gas fresh air atmosphere (vM). 2. Apparatus according to claim 1, characterized, that the sensor unit (Sb) with another Gasatmo Sphere from ambient air (L) or fresh air (F) beauf that is separate from the other two, the Sensor unit (Sb) acting gas atmospheres (R, vM) is held 3. Apparatus according to claim 1 or 2, characterized, that the sensor unit (Sb) each at the end of two stitches is arranged, wherein the first stub from the exhaust gas recirculation line (RL) starts, and the second stub line from the inlet line (ELt) emanates. 4. Apparatus according to claim 1 or 2, characterized, that the sensor unit (Sb) as a link between Exhaust gas recirculation line (RL) and inlet line (ELt) is trained. 5. Apparatus according to claim 1, characterized, that the sensor unit (Sb) in a common wall exhaust gas recirculation line (RL) and inlet line (ELt) is integrated.   6. Apparatus according to claim 1 or 2, characterized, that the sensor unit (Sb) in the wall of the exhaust gas return management line (RL) is integrated, in Be rich, in which the exhaust gas recirculation line in the manner of a Immersion tube inside and inlet line (ELt) ange is orders. 7. Apparatus according to claim 6, characterized, that the sensor unit (Sb) in the wall of the inlet line (ELt) is integrated and contact to the environment air (L) or fresh air (F). 8. Device according to one of the preceding claims, characterized, the sensor unit (Sb) is an electrochemical cell comprising a selectively ion-conducting membrane (M), wherein the ion-conducting membrane (M) selectively to a gas is that in the exhaust (A) in much greater Konzentra tion is present than in the ambient air (L) or in the deadline (F). 9. Device according to one of the preceding claims 1 to 8th, characterized, the sensor unit (Sb) is an electrochemical cell comprising a selectively ion-conducting membrane (M), the two sides with a potential-forming layer (Pb) is provided, wherein the ion-conducting membrane (M) is an ion conducts, which also in the potential-forming layer (Pb) is available. 10. Apparatus according to claim 9, characterized, that at least one of the potential-forming layers (Pb) simultaneously performs the function of an electrode.   11. Device according to one of the preceding claims 1 to 8th, characterized, the sensor unit (Sb) is an electrochemical cell with a selectively oxygen-ion-conducting membrane (M1). 12. Device according to one of the preceding claims 1 to 8th, characterized, that the sensor unit (Sb) two gas sensors (S1, S2) to summarizes, both on a component present in the exhaust gas are selective, wherein a sensor (S1) with a Abgasatmo sphere (R) within the exhaust gas recirculation line (RL) is applied and the other sensor (S2) with an in within the inlet pipe (ELt) after the confluence of the Ab Gas recirculation line (RL) existing gas atmosphere (vM) from exhaust and fresh air is applied. 13. Device according to claim 12, characterized, that the two gas sensors (S1, S2) to a gas selectively are in the exhaust (A) in much greater Konzentra tion is present than in the ambient air (L) or in the fresh air (F). 14. The apparatus of claim 12 or 13, characterized in that the two gas sensors (S1, S2) to H ₂ , HC, NO, NO ₂ , NO x, N ₂ O, SO ₂ , SO ₃ , SOx, H ₂ O, CO or CO _{2 are} sensitive. 15. Device according to claim 12, characterized, the sensor unit (Sb) has two resistive oxygens sors (RSS1, RSS2).   16. Device according to claim 12, characterized, that the sensor unit (Sb) two amperometric Sauer fabric sensors (ASS1, ASS2). 17. Device according to claim 12, characterized, the sensor unit (Sb) has two amperometric NOx Sensors (ANS1, ANS2) includes. 18. Device according to one of the preceding claims 1 to 8th, characterized, that the sensor unit (Sb) an amperometric Sauer fabric sensor (ASS) and an electrochemical cell with egg a selectively ion-conducting membrane (M). 19. Device according to claim 18, characterized, that for the amperometric oxygen sensor (ASS) and for the electrochemical cell the same membrane (M) or separate membranes are used. 20. Device according to one of the preceding claims 1 to 8th, characterized, that the sensor unit (Sb) is a resistive oxygen Sensor (RSS) and an electrochemical cell with a selectively ion-conducting membrane (M).