EP1232391A2 - Method for determining nox concentration - Google Patents
Method for determining nox concentrationInfo
- Publication number
- EP1232391A2 EP1232391A2 EP00989790A EP00989790A EP1232391A2 EP 1232391 A2 EP1232391 A2 EP 1232391A2 EP 00989790 A EP00989790 A EP 00989790A EP 00989790 A EP00989790 A EP 00989790A EP 1232391 A2 EP1232391 A2 EP 1232391A2
- Authority
- EP
- European Patent Office
- Prior art keywords
- nox concentration
- air ratio
- exhaust gas
- measuring cell
- measurement error
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Withdrawn
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Classifications
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N27/00—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
- G01N27/26—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating electrochemical variables; by using electrolysis or electrophoresis
- G01N27/403—Cells and electrode assemblies
- G01N27/406—Cells and probes with solid electrolytes
- G01N27/407—Cells and probes with solid electrolytes for investigating or analysing gases
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N27/00—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
- G01N27/26—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating electrochemical variables; by using electrolysis or electrophoresis
- G01N27/403—Cells and electrode assemblies
- G01N27/406—Cells and probes with solid electrolytes
- G01N27/407—Cells and probes with solid electrolytes for investigating or analysing gases
- G01N27/4073—Composition or fabrication of the solid electrolyte
- G01N27/4074—Composition or fabrication of the solid electrolyte for detection of gases other than oxygen
Definitions
- the invention relates to a method for determining the NOx concentration in the exhaust gas of an internal combustion engine according to the preamble of claim 1.
- a thick-film sensor To measure the NOx concentration in a gas, for example in the exhaust gas of an internal combustion engine, it is known to use a thick-film sensor.
- a thick-film sensor is described, for example, in the publication N. Kato et al. , "Thick Film Zr0 2 NOx Sensor for the Measurement of Low NOx Concentration ,,, Society of Automotive Engineers, publication 980170, 1989, or in N. Kato et al. , “Performance of Thick Film NOx Sensor on Diesel and Gasoline Engines ,,, Society of Automotive Engineers, publication 970858, 1997.
- This sensor has two measuring cells and consists of a zirconium oxide that conducts oxygen ions.
- a first oxygen concentration is set by means of a first oxygen ion pump current, with no decomposition of NOx taking place.
- a second measuring cell which is connected to the first via a diffusion barrier, the oxygen content is further reduced by means of a second oxygen ion pump current.
- the decomposition of NOx at a measuring electrode leads to a third oxygen ion pump current, which is a measure of the NOx concentration.
- the entire sensor is brought to an elevated temperature, for example 750 ° C., by means of an electric heater.
- This measurement of the NOx concentration results in a deviation of the true NOx concentration, since a slip of oxygen from the first into the second chamber leads to a falsification of the NOx measured value.
- Pumping out the acid Material slip in the second cell reduces the oxygen content falsifying the measurement signal considerably, but not completely, since oxygen that does not come from the decomposition of NOx is still included.
- the invention is based on the knowledge that the measurement error of the value for the NOx concentration supplied by a NOx measuring sensor constructed in a two-chamber construction depends on the level of the oxygen concentration in the exhaust gas of an internal combustion engine.
- the sensor cannot measure the oxygen concentration.
- the first oxygen ion pump current is a direct measure of the air ratio ⁇ of the exhaust gas. If one does not relate this measurement error to the
- largely linear means that higher order terms only have to be taken into account with very small coefficients.
- An air ratio signal preferably the 1 / ⁇ value of the exhaust gas, is thus obtained from the first oxygen ion pump current in the first measuring cell, by means of which the measurement error is determined using a relationship between the air ratio signal and measurement error.
- the measured NOx concentration is then corrected for this measurement error.
- the relationship is preferably determined beforehand in a calibration measurement, so that the measurement error in the form of a characteristic of, a characteristic curve or a functional relationship.
- a characteristic curve is also determined which reflects the relationship between the first oxygen ion pump current in the first cell and the air ratio signal, for example 1 / ⁇ or another function of ⁇ .
- the relationship between the first oxygen ion pumping current and 1 / ⁇ is surprisingly largely linear, so that it is further advantageous to select 1 / ⁇ as the air ratio signal.
- the method according to the invention has the advantage that only multiplications, subtractions and additions are necessary when correcting the measured NOx concentration. A division that would unduly stress the computing power of an inexpensive microcontroller is not required.
- FIG. 1 shows a schematic representation of a device for carrying out the method according to the invention
- Fig. 2 is a schematic sectional view of a NOx sensor
- FIG. 3 shows a schematic flow diagram for carrying out the method according to the invention.
- a section through a NOx sensor 1 is shown schematically.
- This sensor 1 is used in the device shown in FIG. 1 as a sensor 24 for loading Mood of the NOx concentration in the exhaust tract 27 of an internal combustion engine 20 is used.
- the measured values of the NOx sensor 24 are read out by a control unit 23, which is connected to the NOx sensor 24, and fed to an operating control device 25 of the internal combustion engine 20, which controls a fuel supply system 21 of the internal combustion engine 20 so that a NOx reducing catalytic converter 28, which in this case is located upstream of the NOx sensor 24 in the exhaust tract 27 of the internal combustion engine 20, shows optimal operating behavior.
- the sensor 24, 1 is shown in more detail in FIG. 2.
- the exhaust gas diffuses through the diffusion barrier 3 into a first measuring cell 4.
- the oxygen content in this measuring cell is measured by tapping a Nernst voltage between a first electrode 5 and a reference electrode 11 exposed to ambient air.
- the reference electrode 11 is arranged in an air duct 12 into which ambient air passes through an opening 14.
- the tapped Nernst voltage is fed to an 8-bit microcontroller which serves as controller C0 and which provides a control voltage VSO.
- controller C0 which controls a voltage-controlled current source UI0 which drives a first oxygen ion pump current IP0 through the solid electrolyte 2 of the sensor 1 between the first electrode 5 and an outer electrode 6.
- a predetermined oxygen concentration is regulated by the regulator C0 m of the first measuring cell 4 by means of the control voltage VSO. This is measured via the Nernst voltage between the electrode 5 and the reference electrode 11, so that the control loop of the controller C0 is closed.
- the first oxygen ion pump current is a measure of the air ratio in the exhaust gas, as is known from lambda probes.
- the circuit arrangement described thus sets a predetermined oxygen concentration in the first measuring cell 4.
- the second measuring cell 8 is connected to the first measuring cell 4 via a further diffusion barrier 7.
- the gas present in the first measuring cell 4 diffuses into the second measuring cell 8 through this diffusion barrier 7.
- a second oxygen concentration is set in the second measuring cell via a circuit arrangement.
- a second Nernst voltage is tapped between a second electrode 9 and the reference electrode 11 and fed to a regulator C1, which provides a second actuating voltage VS1 with which a second voltage-controlled current source Uli is controlled.
- the circuit arrangement for driving the oxygen ion pump current IP1 out of the second measuring cell 8 thus corresponds to the circuit arrangement for the first measuring cell 4.
- the circuit arrangement drives the oxygen ion pumping current IP1 in such a way that a predetermined oxygen concentration is established in the second measuring cell 8.
- This oxygen concentration is chosen so that NOx is not affected by the processes taking place, in particular no decomposition takes place.
- the NOx is now pumped at the measuring electrode 10, which can be configured catalytically, in a third oxygen ion pumping current IP2 from the measuring electrode 10 to the outer electrode 6. Since the residual oxygen content in the measuring cell 8 has been reduced sufficiently, this oxygen ion pumping current IP2 is essentially carried only by oxygen ions which originate from the decomposition of NOx at the measuring electrode 10. The pump current IP2 is therefore a measure of the NOx concentration in the measuring cell 8 and thus in the exhaust gas to be measured.
- This pump current IP2 is driven by a voltage-controlled current source UI2, the actuating voltage VS2 of which is predetermined by a regulator C2, which controls the Nernst voltage between the measuring electrode 10 and the Taps reference electrode 11 and regulates a predetermined Nernst voltage by specifying the control voltage VS2.
- the residual oxygen content of the measuring cell 8 is only ideally zero, since a slip of oxygen from the first into the second measuring cell still causes the measured NOx concentration to depend on the oxygen concentration in the exhaust gas.
- an oxygen signal 1 / LAM is obtained from the first oxygen ion pumping current IPO in the first measuring cell 4, which signal expresses the air ratio in the exhaust gas.
- the conversion of the first oxygen ion pump current IPO is carried out using a characteristic curve 15 or a characteristic map which assigns a 1 / ⁇ value to each current, which in this case is the air ratio signal 1 / LAM.
- the characteristic curve 15 was previously determined for the respective measuring sensor 1 in a calibration measurement.
- This air ratio signal 1 / LAM is implemented with a further characteristic curve 16 m, a measurement error NOx_D.
- the characteristic curve 16 was obtained from a corresponding calibration measurement of the sensor 1 and prints out the relationship between the measurement error and 1 / LAM.
- the conversion using a characteristic curve is replaced by a conversion using a functional relationship. If the 1 / ⁇ value is taken as the air ratio signal, there is a largely linear relationship. If one cannot rely on such a substantially linear relationship, the characteristic curve 16 is stored instead of a function. In the following, however, it is assumed that the 1 / ⁇ value is used as the air ratio signal 1 / LAM and thus the truncation is based on a largely linear relationship. Then through simple multiplication of the value of the air ratio signal 1 / LAM by a multiplication factor and addition of an addition factor, a measurement error N0x_D can be obtained. The corrected NOx concentration NOx_C is obtained by simply multiplying this measurement error N0x_D, which is then implemented, for example, as a correction multiplier, in arithmetic operation 17 by the measured NOx concentration NOx-M.
- the characteristic curve 15 can be combined with this characteristic curve 16, so that directly from the first Oxygen ion pump current IPO the measurement error N0x_D, for example as a multiplication or addition correction factor. Then one step is omitted because the generation of the air ratio signal 1 / LAM is dispensed with. However, if this air ratio signal 1 / LAM is required, for example for other control or regulating functions when operating the internal combustion engine, it can of course still be generated from the first oxygen ion pumping current IPO.
Abstract
The invention relates to the measurement of the NOx concentration in the exhaust gas of an internal combustion engine (20), whereby a thick-layer measurement sensor (24), comprising two measurement cells is employed. The 1/ lambda value of the exhaust gas is determined from the pumped oxygen ion stream flowing into the first measuring cell, for example, by means of a characteristic field and from this value, for example, by means of a characteristic curve obtained previously in a calibration determination, a measurement error is determined, with which the measured Nox concentration may be corrected. The basis of the invention is the knowledge that the measured error depends on the air ratio in the exhaust gas. A complicated division may be avoided in the correction by expressing the above through the 1/ lambda value.
Description
Beschreibungdescription
Verfahren zur Bestimmung der NOx-KonzentrationMethod for determining the NOx concentration
Die Erfindung betrifft ein Verfahren zur Bestimmung der NOx- Konzentration im Abgas einer Brennkraftmaschine gemäß dem Oberbegriff des Patentanspruchs 1.The invention relates to a method for determining the NOx concentration in the exhaust gas of an internal combustion engine according to the preamble of claim 1.
Zur Messung der NOx-Konzentration in einem Gas, z.B. im Abgas einer Brennkraftmaschine, ist es bekannt, einen Dickschicht- Meßaufnehmer zu verwenden. Ein solcher Meßaufnehmer ist beispielsweise in der Veröffentlichung N. Kato et al . , „Thick Film Zr02 NOx Sensor for the Measurement of Low NOx Concentration,,, Society of Automotive Engineers, Veröffentli- chung 980170, 1989, oder in N. Kato et al . , „Performance of Thick Film NOx Sensor on Diesel and Gasoline Engines,,, Society of Automotive Engineers, Veröffentlichung 970858, 1997, beschrieben. Dieser Meßaufnehmer weist zwei Meßzellen auf und besteht aus einem Sauerstoffionen leitenden Zirkoniumoxid. Er verwirklicht folgendes Meßkonzept: In einer ersten Meßzelle, der das zu messende Gas über eine Diffusionsbarriere zugeführt wird, wird mittels eines ersten Sauerstoffionen-Pumpstroms eine erste Sauerstoffkonzentration eingestellt, wobei keine Zersetzung von NOx stattfinden soll. In einer zweiten Meßzelle, die über eine Diffusionsbarriere mit der ersten verbunden ist, wird der Sauerstoffgehalt mittels eines zweiten Sauerstoffionen-Pumpstroms weiter abgesenkt. Die Zersetzung von NOx an einer Meßelektrode führt zu einem dritten Sauerstoffionen-Pu pstrom, der ein Maß für die NOx-Konzentration ist. Der gesamte Meßaufnehmer wird dabei mittels eines elektrischen Heizers auf eine erhöhte Temperatur, z.B. 750°C, gebracht.To measure the NOx concentration in a gas, for example in the exhaust gas of an internal combustion engine, it is known to use a thick-film sensor. Such a sensor is described, for example, in the publication N. Kato et al. , "Thick Film Zr0 2 NOx Sensor for the Measurement of Low NOx Concentration ,,, Society of Automotive Engineers, publication 980170, 1989, or in N. Kato et al. , "Performance of Thick Film NOx Sensor on Diesel and Gasoline Engines ,,, Society of Automotive Engineers, publication 970858, 1997. This sensor has two measuring cells and consists of a zirconium oxide that conducts oxygen ions. He realizes the following measurement concept: In a first measuring cell, to which the gas to be measured is fed via a diffusion barrier, a first oxygen concentration is set by means of a first oxygen ion pump current, with no decomposition of NOx taking place. In a second measuring cell, which is connected to the first via a diffusion barrier, the oxygen content is further reduced by means of a second oxygen ion pump current. The decomposition of NOx at a measuring electrode leads to a third oxygen ion pump current, which is a measure of the NOx concentration. The entire sensor is brought to an elevated temperature, for example 750 ° C., by means of an electric heater.
Bei dieser Messung der NOx-Konzentration entsteht eine Abwei- chung der wahren NOx-Konzentration, da es durch einen Schlupf von Sauerstoff von der ersten in die zweite Kammer zu einer Verfälschung des NOx-Meßwertes kommt. Das Abpumpen des Sauer-
Stoffschlupfes in der zweiten Zelle reduziert zwar den das Meßsignal verfälschenden Sauerstoffgehalt erheblich, jedoch nicht vollständig, da immer noch Sauerstoff, der nicht aus der Zersetzung von NOx stammt, miterfaßt wird.This measurement of the NOx concentration results in a deviation of the true NOx concentration, since a slip of oxygen from the first into the second chamber leads to a falsification of the NOx measured value. Pumping out the acid Material slip in the second cell reduces the oxygen content falsifying the measurement signal considerably, but not completely, since oxygen that does not come from the decomposition of NOx is still included.
Es ist Aufgabe der vorliegenden Erfindung, ein Verfahren anzugeben, mit dem die NOx-Konzentration im Abgas einer Brennkraftmaschine unter Verwendung des oben beschriebenen Meßaufnehmers exakter erfaßt werden kann.It is an object of the present invention to provide a method with which the NOx concentration in the exhaust gas of an internal combustion engine can be detected more precisely using the sensor described above.
Diese Aufgabe wird durch die Merkmale des Anspruchs 1 gelöst.This object is solved by the features of claim 1.
Die Erfindung geht von der Erkenntnis aus, daß der Meßfehler des von einem in Zweikammerbauweise aufgebauten NOx- Meßaufnehmer gelieferten Wertes für die NOx-Konzentration von der Höhe der Sauerstoffkonzentration im Abgas einer Brennkraftmaschine abhängt. Der Meßwertaufnehmer kann die Sauerstoffkonzentration nicht messen. Der erste Sauerstoffionen- Pumpstrom ist eben ein direktes Maß für das Luftverhältnis λ des Abgases. Bezieht man diesen Meßfehler nun nicht auf dieThe invention is based on the knowledge that the measurement error of the value for the NOx concentration supplied by a NOx measuring sensor constructed in a two-chamber construction depends on the level of the oxygen concentration in the exhaust gas of an internal combustion engine. The sensor cannot measure the oxygen concentration. The first oxygen ion pump current is a direct measure of the air ratio λ of the exhaust gas. If one does not relate this measurement error to the
Sauerstoffkonzentration, sondern auf λ, vorzugsweise auf dessen Kehrwert 1/λ, so zeigt sich, daß der Meßfehler bei vielen Meßaufnehmern durch eine einfache Funktion, bei 1/λ sogar weitgehend linear beschrieben werden kann. Unter weitgehend linear wird dabei verstanden, daß bei einer Reihenentwicklung Terme höherer Ordnung nur noch mit sehr kleinen Koeffizienten berücksichtigt werden müssen.Oxygen concentration, but on λ, preferably on its reciprocal 1 / λ, shows that the measurement error can be described by many sensors with a simple function, at 1 / λ even largely linear. In this context, largely linear means that higher order terms only have to be taken into account with very small coefficients.
Aus dem ersten Sauerstoffionen-Pumpstrom in der ersten Meß- zelle wird somit ein Luftverhältnissignal, vorzugsweise der 1/λ-Wert des Abgases gewonnen, mittels dem der Meßfehler unter Ausnützung eines Zusammenhangs zwischen Luftverhältnissignal und Meßfehler bestimmt wird. Um diesen Meßfehler wird die gemessene NOx-Konzentration dann korrigiert.An air ratio signal, preferably the 1 / λ value of the exhaust gas, is thus obtained from the first oxygen ion pump current in the first measuring cell, by means of which the measurement error is determined using a relationship between the air ratio signal and measurement error. The measured NOx concentration is then corrected for this measurement error.
Vorzugsweise wird der Zusammenhang zuvor in einer Kalibriermessung bestimmt, so daß der Meßfehler in Form eines Kennfei-
des, einer Kennlinie oder eines funktionalen Zusammenhangs vorliegt .The relationship is preferably determined beforehand in a calibration measurement, so that the measurement error in the form of a characteristic of, a characteristic curve or a functional relationship.
Um das Luftverhaltnissignal aus dem ersten Sauerstofflonen- Pumpstrom gewinnen zu können, wird weiter eine Kennlinie bestimmt, die den Zusammenhang zwischen erstem Sauerstofflonen- Pumpstrom in der ersten Zelle und dem Luftverhaltnissignal, beispielsweise 1/λ oder einer anderen Funktion von λ wiedergibt. Dabei ist der Zusammenhang zwischen erstem SauerstoffI- onen-Pumpstrom und 1/λ überraschenderweise weitgehend linear, so daß es weiter vorteilhaft ist, als Luftverhaltnissignal 1/λ zu wählen.In order to be able to obtain the air ratio signal from the first oxygen ion pump current, a characteristic curve is also determined which reflects the relationship between the first oxygen ion pump current in the first cell and the air ratio signal, for example 1 / λ or another function of λ. The relationship between the first oxygen ion pumping current and 1 / λ is surprisingly largely linear, so that it is further advantageous to select 1 / λ as the air ratio signal.
Das erfmdungsgemaße Verfahren hat den Vorteil, daß bei der Korrektur der gemessenen NOx-Konzentration nur Multiplikationen, Subtraktionen und Additionen notig sind. Eine Division, die die Rechenleistung eines kostengünstigen Mikrokontrollers übermäßig stark beanspruchen wurde, ist nicht erforderlich.The method according to the invention has the advantage that only multiplications, subtractions and additions are necessary when correcting the measured NOx concentration. A division that would unduly stress the computing power of an inexpensive microcontroller is not required.
Vorteilhafte Ausgestaltungen der Erfindung sind in den Ansprüchen gekennzeichnet.Advantageous embodiments of the invention are characterized in the claims.
Die Erfindung wird nachfolgend anhand der Zeichnung naher beschrieben. Die Zeichnung zeigt:The invention is described below with reference to the drawing. The drawing shows:
Fig. 1 eine schematische Darstellung einer Vorrichtung zur Durchfuhrung des erfmdungsgemaßen Verfahrens,1 shows a schematic representation of a device for carrying out the method according to the invention,
Fig. 2 eine schematische Schnittdarstellung eines NOx- Meßaufnehmers undFig. 2 is a schematic sectional view of a NOx sensor and
Fig. 3 ein schematisches Flußdiagramm zur Durchfuhrung des erfmdungsgemaßen Verfahrens.3 shows a schematic flow diagram for carrying out the method according to the invention.
In Fig. 2 ist ein Schnitt durch einen NOx-Meßaufnehmer 1 schematisch dargestellt. Dieser Meßaufnehmer 1 wird in der in Fig. 1 dargestellten Vorrichtung als Meßaufnehmer 24 zur Be-
Stimmung der NOx-Konzentration im Abgastrakt 27 einer Brennkraftmaschine 20 verwendet. Dazu werden die Meßwerte des NOx- Meßaufnehmers 24 von einer Steuereinheit 23 ausgelesen, die mit dem NOx-Meßaufnehmer 24 verbunden ist, und einem Be- triebssteuergerat 25 der Brennkraftmaschine 20 zugeführt, das ein Kraftstoffzufuhrsystem 21 der Brennkraftmaschine 20 so ansteuert, daß ein NOx-reduzierender Katalysator 28, der in diesem Fall stromauf des NOx-Meßaufnehmers 24 im Abgastrakt 27 der Brennkraftmaschine 20 liegt, optimales Betriebsverhal- ten zeigt.In Fig. 2 a section through a NOx sensor 1 is shown schematically. This sensor 1 is used in the device shown in FIG. 1 as a sensor 24 for loading Mood of the NOx concentration in the exhaust tract 27 of an internal combustion engine 20 is used. For this purpose, the measured values of the NOx sensor 24 are read out by a control unit 23, which is connected to the NOx sensor 24, and fed to an operating control device 25 of the internal combustion engine 20, which controls a fuel supply system 21 of the internal combustion engine 20 so that a NOx reducing catalytic converter 28, which in this case is located upstream of the NOx sensor 24 in the exhaust tract 27 of the internal combustion engine 20, shows optimal operating behavior.
Der Meßaufnehmer 24, 1 ist in Fig. 2 detaillierter dargestellt. Der aus einem Festkorperelektrolyten 2, m diesem Fall Zr02 bestehende Meßaufnehmer 1 nimmt über eine Diffusi- onsbarπere 3 das zu messende Abgas auf, dessen NOx- Konzentration bestimmt werden soll. Das Abgas diffundiert durch die Diffusionsbarriere 3 in eine erste Meßzelle 4. Der Sauerstoffgehalt in dieser Meßzelle wird durch Abgriff einer Nernstspannung zwischen einer ersten Elektrode 5 und einer Umgebungsluft ausgesetzten Referenzelektrode 11 gemessen. Dabei ist die Referenzelektrode 11 m einem Luftkanal 12 angeordnet, in den über eine Öffnung 14 Umgebungsluft gelangt.The sensor 24, 1 is shown in more detail in FIG. 2. The measuring sensor 1, consisting of a solid electrolyte 2, in this case Zr0 2 , receives the exhaust gas to be measured, the NOx concentration of which is to be determined, via a diffusion bar 3. The exhaust gas diffuses through the diffusion barrier 3 into a first measuring cell 4. The oxygen content in this measuring cell is measured by tapping a Nernst voltage between a first electrode 5 and a reference electrode 11 exposed to ambient air. In this case, the reference electrode 11 is arranged in an air duct 12 into which ambient air passes through an opening 14.
Die abgegriffene Nernstspannung wird einem als Regler C0 die- nenden 8-Bιt MikroController zugeführt, der eine Stellspannung VSO bereitstellt. Diese steuert eine spannungsgesteuerte Stromquelle UI0 an, die einen ersten Sauerstofflonen- Pumpstrom IP0 durch den Festkorperelektrolyten 2 des Meßaufnehmers 1 zwischen der ersten Elektrode 5 und einer Außen- elektrode 6 treibt. Dabei wird mittels der Stellspannung VSO vom Regler C0 m der ersten Meßzelle 4 eine vorbestimmte Sauerstoffkonzentration eingeregelt. Diese wird über die Nernstspannung zwischen der Elektrode 5 und der Referenzelektrode 11 gemessen, so daß der Regelkreis des Reglers C0 geschlossen ist. Der erste Sauerstofflonen-Pumpstrom ist ein Maß für das Luftverhaltnis im Abgas, wie von Lambda-Sonden bekannt ist.
Die beschriebene Schaltkreisanordnung stellt so in der ersten Meßzelle 4 eine vorbestimmte Sauerstoffkonzentration ein. Die zweite Meßzelle 8 ist mit der ersten Meßzelle 4 über eine weitere Diffusionsbarriere 7 verbunden. Durch diese Diffusi- onsbarriere 7 diffundiert das in der ersten Meßzelle 4 vorhandene Gas in die zweite Meßzelle 8. In der zweiten Meßzelle wird über eine Schaltkreisanordnung eine zweite Sauerstoffkonzentration eingestellt. Dazu wird zwischen einer zweiten Elektrode 9 und der Referenzelektrode 11 eine zweite Nernst- Spannung abgegriffen und einem Regler Cl zugeführt, der eine zweite Stellspannung VS1 bereitstellt, mit der eine zweite spannungsgesteuerte Stromquelle Uli angesteuert wird. Die Schaltkreisanordnung zum Treiben des Sauerstoffionen- Pumpstroms IP1 aus der zweiten Meßzelle 8 heraus entspricht somit der Schaltkreisanordnung für die erste Meßzelle 4.The tapped Nernst voltage is fed to an 8-bit microcontroller which serves as controller C0 and which provides a control voltage VSO. This controls a voltage-controlled current source UI0 which drives a first oxygen ion pump current IP0 through the solid electrolyte 2 of the sensor 1 between the first electrode 5 and an outer electrode 6. A predetermined oxygen concentration is regulated by the regulator C0 m of the first measuring cell 4 by means of the control voltage VSO. This is measured via the Nernst voltage between the electrode 5 and the reference electrode 11, so that the control loop of the controller C0 is closed. The first oxygen ion pump current is a measure of the air ratio in the exhaust gas, as is known from lambda probes. The circuit arrangement described thus sets a predetermined oxygen concentration in the first measuring cell 4. The second measuring cell 8 is connected to the first measuring cell 4 via a further diffusion barrier 7. The gas present in the first measuring cell 4 diffuses into the second measuring cell 8 through this diffusion barrier 7. A second oxygen concentration is set in the second measuring cell via a circuit arrangement. For this purpose, a second Nernst voltage is tapped between a second electrode 9 and the reference electrode 11 and fed to a regulator C1, which provides a second actuating voltage VS1 with which a second voltage-controlled current source Uli is controlled. The circuit arrangement for driving the oxygen ion pump current IP1 out of the second measuring cell 8 thus corresponds to the circuit arrangement for the first measuring cell 4.
Die Schaltkreisanordnung treibt den Sauerstoffionen-Pumpstrom IP1 so, daß sich in der zweiten Meßzelle 8 eine vorbestimmte Sauerstoffkonzentration einstellt .The circuit arrangement drives the oxygen ion pumping current IP1 in such a way that a predetermined oxygen concentration is established in the second measuring cell 8.
Diese Sauerstoffkonzentration wird dabei so gewählt, daß NOx von den ablaufenden Vorgängen nicht betroffen ist, insbesondere keine Zersetzung stattfindet. Das NOx wird nun an der Meßelektrode 10, die katalytisch ausgestaltet sein kann, in einem dritten Sauerstoffionen-Pumpstrom IP2 von der Meßelektrode 10 zur Außenelektrode 6 hin gepumpt. Da der Restsauerstoffgehalt in der Meßzelle 8 ausreichend abgesenkt ist, wird dieser Sauerstoffionen-Pumpstrom IP2 im wesentlichen nur von Sauerstoffionen getragen, die aus der Zersetzung von NOx an der Meßelektrode 10 stammen. Der Pumpstrom IP2 ist somit ein Maß für die NOx-Konzentration in der Meßzelle 8 und somit im zu messenden Abgas.This oxygen concentration is chosen so that NOx is not affected by the processes taking place, in particular no decomposition takes place. The NOx is now pumped at the measuring electrode 10, which can be configured catalytically, in a third oxygen ion pumping current IP2 from the measuring electrode 10 to the outer electrode 6. Since the residual oxygen content in the measuring cell 8 has been reduced sufficiently, this oxygen ion pumping current IP2 is essentially carried only by oxygen ions which originate from the decomposition of NOx at the measuring electrode 10. The pump current IP2 is therefore a measure of the NOx concentration in the measuring cell 8 and thus in the exhaust gas to be measured.
Dieser Pumpstrom IP2 wird wie die vorherigen Pumpströme von einer spannungsgesteuerten Stromquelle UI2 getrieben, deren Stellspannung VS2 von einem Regler C2 vorgegeben wird, der die Nernstspannung zwischen der der Meßelektrode 10 und der
Referenzelektrode 11 abgreift und durch Vorgabe der Stellspannung VS2 eine vorbestimmte Nernstspannung einregelt.This pump current IP2, like the previous pump currents, is driven by a voltage-controlled current source UI2, the actuating voltage VS2 of which is predetermined by a regulator C2, which controls the Nernst voltage between the measuring electrode 10 and the Taps reference electrode 11 and regulates a predetermined Nernst voltage by specifying the control voltage VS2.
Der Restsauerstoffgehalt der Meßzelle 8 ist jedoch nur ldeal- erweise Null, da ein Schlupf von Sauerstoff von der ersten in die zweite Meßzelle immer noch eine Abhängigkeit der gemessenen NOx-Konzentration von der Sauerstoffkonzentration im Abgas bewirkt.However, the residual oxygen content of the measuring cell 8 is only ideally zero, since a slip of oxygen from the first into the second measuring cell still causes the measured NOx concentration to depend on the oxygen concentration in the exhaust gas.
Diese Abhängigkeit wird nun rechnerisch nach dem in Fig. 3 schematisch dargestellten Verfahren korrigiert. Zuerst wird aus dem ersten Sauerstoffionen-Pumpstrom IPO in der ersten Meßzelle 4 ein SauerstoffSignal 1/LAM gewonnen, welches das Luftverhaltnis im Abgas ausdruckt. Die Umwandlung des ersten Sauerstoffionen-Pumpstroms IPO erfolgt dabei mit einer Kennlinie 15 oder einem Kennfeld, das jedem Strom einen 1/λ-Wert, der m diesem Fall das Luftverhaltnissignal 1/LAM ist, zuordnet. Die Kennlinie 15 wurde zuvor für den jeweiligen Meßaufnehmer 1 in einer Kalibπermessung bestimmt.This dependency is now corrected arithmetically using the method shown schematically in FIG. 3. First, an oxygen signal 1 / LAM is obtained from the first oxygen ion pumping current IPO in the first measuring cell 4, which signal expresses the air ratio in the exhaust gas. The conversion of the first oxygen ion pump current IPO is carried out using a characteristic curve 15 or a characteristic map which assigns a 1 / λ value to each current, which in this case is the air ratio signal 1 / LAM. The characteristic curve 15 was previously determined for the respective measuring sensor 1 in a calibration measurement.
Dieses Luftverhaltnissignal 1/LAM wird mit einer weiteren Kennlinie 16 m einen Meßfehler NOx_D umgesetzt. Die Kennlinie 16 wurde aus einer entsprechenden Kalibriermessung des Meßaufnehmers 1 gewonnen und druckt den Zusammenhang zwischen Meßfehler und 1/LAM aus.This air ratio signal 1 / LAM is implemented with a further characteristic curve 16 m, a measurement error NOx_D. The characteristic curve 16 was obtained from a corresponding calibration measurement of the sensor 1 and prints out the relationship between the measurement error and 1 / LAM.
Für den Fall, daß sich ein funktionaler Zusammenhang zwischen Meßfehler NOx_D und Luftverhaltnissignal 1/LAM finden laßt, wird die Umsetzung per Kennlinie durch eine Umrechnung per funktionalem Zusammenhang ersetzt. Wird als Luftverhaltnissignal der 1/λ-Wert genommen, ergibt sich ein weitgehend linearer Zusammenhang. Kann man sich nicht auf einen solchen wesentlich linearen Zusammenhang stutzen, ist anstatt einer Funktion die Kennlinie 16 hinterlegt. Im folgenden wird je- doch davon ausgegangen, daß der 1/λ-Wert als Luftverhaltnissignal 1/LAM verwendet wird und somit die Stutzung auf einen weitgehend linearen Zusammenhang erfolgt. Dann kann durch
einfache Multiplikation des Wertes des Luftverhältnissignals 1/LAM mit einem Multiplikationsfaktor sowie Addition eines Additionsfaktors ein Meßfehler N0x_D erhalten werden. Durch eine einfache Multiplikation dieses dann beispielsweise als Korrekturmultiplikator realisierten Meßfehlers N0x_D in der Rechenoperation 17 mit der gemessenen NOx-Konzentration NOx-M erhält man die korrigierte NOx-Konzentration NOx_C.In the event that a functional relationship between measurement error NOx_D and air ratio signal 1 / LAM can be found, the conversion using a characteristic curve is replaced by a conversion using a functional relationship. If the 1 / λ value is taken as the air ratio signal, there is a largely linear relationship. If one cannot rely on such a substantially linear relationship, the characteristic curve 16 is stored instead of a function. In the following, however, it is assumed that the 1 / λ value is used as the air ratio signal 1 / LAM and thus the truncation is based on a largely linear relationship. Then through simple multiplication of the value of the air ratio signal 1 / LAM by a multiplication factor and addition of an addition factor, a measurement error N0x_D can be obtained. The corrected NOx concentration NOx_C is obtained by simply multiplying this measurement error N0x_D, which is then implemented, for example, as a correction multiplier, in arithmetic operation 17 by the measured NOx concentration NOx-M.
Dabei wird weder bei der Bestimmung des Meßfehlers NOx_D aus dem Luftverhaltnissignal 1/LAM noch bei der Berechnung der korrigierten NOx-Konzentration NOx_C eine Division erforderlich, die in der Regel eine Gleitkommaarithmetik mit sich brächte und deshalb einen aufwendigen Mikrokontroller erforderte. Stattdessen kann ein einfacher kostengünstiger Mikro- kontroller verwendet werden.There is no need for a division when determining the measurement error NOx_D from the air ratio signal 1 / LAM or when calculating the corrected NOx concentration NOx_C, which would normally involve floating point arithmetic and therefore required a complex microcontroller. Instead, a simple, inexpensive microcontroller can be used.
Ist es nicht möglich, sich bei der Bestimmung des Meßfehlers NOx_D aus dem Luftverhaltnissignal 1/LAM auf einen weitgehend linearen Zusammenhang zu stützen, sondern wird eine Kennlinie 16 eingesetzt, kann man die Kennlinie 15 mit dieser Kennlinie 16 vereinigen, so daß direkt aus dem ersten Sauerstoffionen- Pumpstrom IPO der Meßfehler N0x_D, beispielsweise als Mul- tiplikations- oder Additionskorrekturfaktor erhalten wird. Dann fällt ein Arbeitsschritt weg, da auf die Generierung des Luftverhältnissignals 1/LAM verzichtet wird. Benötigt man allerdings dieses Luftverhaltnissignal 1/LAM, beispielsweise für andere Steuerungs- oder Regelungsfunktionen beim Betrieb der Brennkraftmaschine, kann es natürlich dennoch aus dem ersten Sauerstoffionen-Pumpstrom IPO erzeugt werden.
If it is not possible to rely on a largely linear relationship when determining the measurement error NOx_D from the air ratio signal 1 / LAM, but if a characteristic curve 16 is used, the characteristic curve 15 can be combined with this characteristic curve 16, so that directly from the first Oxygen ion pump current IPO the measurement error N0x_D, for example as a multiplication or addition correction factor. Then one step is omitted because the generation of the air ratio signal 1 / LAM is dispensed with. However, if this air ratio signal 1 / LAM is required, for example for other control or regulating functions when operating the internal combustion engine, it can of course still be generated from the first oxygen ion pumping current IPO.
Claims
1. Verfahren zur Bestimmung der NOx-Konzentration im Abgas einer Brennkraftmaschine mittels eines Meßaufnehmers mit1. Method for determining the NOx concentration in the exhaust gas of an internal combustion engine by means of a measuring sensor
- einer ersten Meßzelle, in die ein Teil des Abgases eingeführt wird und in der eine erste Sauerstoffkonzentration durch einen Sauerstoffionen-Pumpstrom eingestellt wird,a first measuring cell, into which part of the exhaust gas is introduced and in which a first oxygen concentration is set by an oxygen ion pumping current,
- einer zweiten Meßzelle, die mit der ersten Meßzelle verbun- den ist und m der eine zweite Sauerstoffkonzentration eingestellt wird, wobei- a second measuring cell, which is connected to the first measuring cell and m is set to a second oxygen concentration, wherein
- die NOx-Konzentration in der zweiten Meßzelle gemessen wird, d a d u r c h g e k e n n z e i c h n e t, daß a) aus dem Sauerstoffionen-Pumpstrom ein Luftverhaltnissignal bestimmt wird, das eine Funktion des λ-Wertes des Abgases wiedergibt, b) aus dem Luftverhaltnissignal ein Meßfehler bestimmt wird, der die Abweichung der gemessenen NOx-Konzentration von der wahren NOx-Konzentration wiedergibt, und c) die gemessene NOx-Konzentration um den Meßfehler korrigiert wird.- The NOx concentration is measured in the second measuring cell, characterized in that a) an air ratio signal is determined from the oxygen ion pump current, which represents a function of the λ value of the exhaust gas, b) a measurement error is determined from the air ratio signal, which Deviates the measured NOx concentration from the true NOx concentration, and c) the measured NOx concentration is corrected by the measurement error.
2. Verfahren nach Anspruch 1, d a d u r c h g e k e n n z e ic h n e t, daß der Zusammenhang zwischen Luftverhaltnissignal und Meßfehler in einer Kalibriermessung bestimmt wird, in der der Meßaufnehmer verschiedenen Gasgemischen ausgesetzt wird, und der Meßfehler erfaßt und m Form eines Kennfeldes oder einer Kennlinie oder eines funktionalen Zusammenhangs beschrieben wird, wobei m den Gasgemischen mindestens λ-Wert und NOx- Konzentration variiert wird.2. The method according to claim 1, dadurchgekennze ic hnet that the relationship between air ratio signal and measurement error is determined in a calibration measurement in which the sensor is exposed to various gas mixtures, and the measurement error is detected and described in the form of a map or a characteristic curve or a functional relationship is, wherein the gas mixtures at least λ value and NOx concentration is varied.
3. Verfahren nach Anspruch 1 oder 2, d a d u r c h g e k e n n z e i c h n e t, daß d e Korrektur im Schritt c) durch Multiplikations-Additions- und/oder Subtraktionsrechenoperationen erfolgt. 3. The method according to claim 1 or 2, characterized in that de correction in step c) is carried out by multiplication-addition and / or subtraction operations.
4. Verfahren nach einem der vorherigen Ansprüche, d a d u r c h g e k e n n z e i c h n e t, daß als Zusammenhang zwischen Luftverhaltnissignal und Meßfehler im Schritt b) eine weitgehend lineare Funktion verwendet wird.4. The method according to any one of the preceding claims, that a largely linear function is used as the relationship between air ratio signal and measurement error in step b).
5. Verfahren nach einem der vorherigen Ansprüche, d a d u r c h g e k e n n z e i c h n e t, daß im Schritt a) auf eine Kennlinie oder ein Kennfeld zugegriffen wird, um das Luftverhaltnissignal aus dem Sauerstoffionen-Pumpstrom zu bestimmen. 5. The method according to any one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that a characteristic or a map is accessed in step a) to determine the air ratio signal from the oxygen ion pump current.
Applications Claiming Priority (3)
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DE19956822 | 1999-11-25 | ||
DE19956822A DE19956822B4 (en) | 1999-11-25 | 1999-11-25 | Method for determining the NOx concentration |
PCT/DE2000/004128 WO2001038864A2 (en) | 1999-11-25 | 2000-11-22 | Method for determining nox concentration |
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EP1232391A2 true EP1232391A2 (en) | 2002-08-21 |
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EP00989790A Withdrawn EP1232391A2 (en) | 1999-11-25 | 2000-11-22 | Method for determining nox concentration |
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EP (1) | EP1232391A2 (en) |
JP (1) | JP4746239B2 (en) |
KR (1) | KR100754535B1 (en) |
DE (1) | DE19956822B4 (en) |
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DE19956822B4 (en) | 2004-01-29 |
WO2001038864A3 (en) | 2002-02-14 |
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WO2001038864A2 (en) | 2001-05-31 |
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