DE19727268C1 - Validation of reductant dosing unit for hot diesel exhaust gas selective catalytic reducer - Google Patents

Abstract

A new method monitors reductant dosing associated with diesel engines or diesel combustion plant. Exhaust temperature is measured using a sensor. Above a limiting temperature, reductant is injected into the exhaust, under pressure. The injection point is upstream of the SCR, i.e. the selective catalytic reducer for NOx. The new method requires reductant injection (16) close to the sensor (18), with at least some reductant reaching it. The time-temperature profile caused by the cooling effect of evaporating reductant, is measured by the sensor. From this profile, a pronouncement is made on the health of the dosing unit (14, 15, 16).

Description

The invention relates to methods for monitoring the reducti ondosing in an SCR catalytic converter according to the Ober understood claims 1, 6 and 12.

A significant reduction in the NO _x emission of a diesel internal combustion engine or a diesel incineration plant can be achieved by using the so-called selective catalytic reduction method. In the SCR process, a reducing agent is injected into the exhaust gas at a point in front of an SCR catalytic converter, so that the chemical reactions in particular on the catalytic converter

4NO + 4NH ₃ + O ₂ → 4N ₂ + 6H ₂ O
2NO ₂ + 4NH ₃ + O ₂ → 3N ₂ + 6H ₂ O

can expire. A suitable reducing agent is, for example, ammonia. For reasons of manageability, ammonia is metered in an aqueous solution or an aqueous solution of urea is metered in, which provides ammonia for the SCR process after hydrolysis. Dosing is carried out by timing the opening of a dosing valve. The reducing agent solution is provided by a pump and a pressure regulator with a defined pressure at the valve. The Reduktionsmit teldosierung must be continuously monitored as an overdose causes ammonia emission, but a Unterdosie tion a high NO _x -Austoß result has.

Exhaust gas sensors can be used to regulate the NO _x reduction system. These sensors can detect malfunctions in the metering only by measuring the NO _x and NH ₃ concentration after the SCR catalytic converter only with a time delay, since depending on the operating state of the internal combustion engine, the catalytic converter, due to its storage capacity, has the effect of the malfunction the NO _x or NH ₃ concentration after the catalyst is delayed.

A method for reducing the nitrogen oxide concentration in the Exhaust gas from an internal combustion engine using one in the exhaust tract behind the SCR catalytic converter is in the DE 43 34 071 C1 described. The detector has one such probably respond to nitrogen monoxide as well as ammonia of the sensor element. The of the nitric oxide and Am monia concentration dependent resistance or the electrical Conductivity of the sensor element is measured and the exhaust gas such an amount of the reducing agent is added at which the electrical resistance of the sensor element is greatest or the electrical conductivity is the smallest.

From DE 42 17 552 C1 an exhaust gas treatment device for internal combustion engines with a catalyst for the selective catalytic reaction of nitrogen oxides from exhaust gases, in particular from exhaust gases from motor vehicle diesel engines with stoichiometric addition of NH ₃ or NH ₃ - releasing substances is known. It has a first sensor which detects the NH ₃ concentration contained in the exhaust gas and which interrupts the addition of the NH ₃ amount when a predetermined upper threshold value is reached. A second sensor detects the NH ₃ adsorbed in the catalyst. When a predetermined lower threshold value is reached, the NH ₃ addition is released again.

The object of the invention is to provide methods with which the reducing agent metering is continuously monitored can.

This task is characterized by the characteristics of the subordinate Pa Claims 1, 6 and 12 solved. Advantageous further training conditions are marked in the subclaims.

The addition of the reducing agent in the hot exhaust gas before the SCR catalyst has due to the evaporation occurring heat results in a change in temperature. The tempe The course of the temperature during the dosing process is monitored, off evaluated and from this a statement about the functionality speed of the dosing device.

It is simple with the method according to the invention possible, the metering device, in particular the metering valve monitor for operability.

Embodiments of the invention will follow with reference to the the drawings explained. It shows:

Fig. 1 is a block diagram of an equipped with an SCR catalytic converter exhaust system of a machine Dieselbrennkraftma,

Fig. 2 shows a typical curve of the output signal of a temperature sensor in the reducing agent dosing,

Fig. 3 is a block diagram of an equipped with an SCR catalyst and an electrically heated mixer exhaust system of a diesel internal combustion engine, and

Fig. 4 shows a typical waveform of the ohmic resistance of the mixer heater with reducing agent metering.

The exhaust system shown schematically in FIG. 1 of an internal combustion engine 10 has an intake tract 11 and an exhaust tract 12 with an SCR catalytic converter 13 of known construction arranged therein. The SCR catalytic converter 13 is upstream of a metering device, consisting of a reducing agent container 14 , a pump 15 and a metering valve 16 . The pump 15 promotes the reducing agent in the reducing agent tank 14 be sensitive, for example ammonia or on monia-releasing substances, which is injected into the exhaust gas upstream of the SCR catalyst 13 by means of the metering valve 16 . The metering valve 16 is controlled by lines not shown from a control unit 17 . This control unit 17 ensures that the exhaust gas a certain, currently necessary amount of the reducing agent can be supplied. In the illustration, the control unit 17 is shown as a separate unit, but it is possible to integrate the function of this control unit in the control unit of the internal combustion engine.

The reducing agent is only metered if the exhaust gas temperature is high enough to evaporate the reducing agent solution and to hydrolyze urea. The temperature of the exhaust gas is measured at a point in front of the SCR catalytic converter by means of a temperature sensor 18 . During the dosing process, the reducing agent or the reducing agent solution is injected into the hot exhaust gas. Due to the heat of evaporation of the solvent, each metering pulse draws heat from the environment. If the reducing agent jet hits the exhaust gas temperature sensor 18 , it is cooled. This jump in temperature can be detected by the control unit 17 , since the sensor temperature changes more quickly due to evaporation of the reducing agent or the reducing agent solution directly on the sensor surface than through changes in the operating state of the internal combustion engine.

The upper part of FIG. 2 shows a typical course of the output signal of the temperature sensor 18 with reducing agent metering. On the abscissa is the temperature T detected by the temperature sensor 18 , on the ordinate the time t wear up. The lower part of FIG. 2 shows the temporal course of the valve current I with which the metering valve 16 is controlled.

The control unit actuates the metering valve 16 by switching on at time t1 and switching off valve current I at time t2. To detect the temperature difference ΔT occurring due to the addition of metering agent, the temperature T1 is detected by means of the control unit, if possible shortly before the reducing agent jet hits the temperature sensor 18 after the metering valve 16 has been actuated. For the determination of the optimal time for the measurement of the sensor signal T1, a delay time Δt1 is defined, in which valve reaction time, running time of the reducing agent beam, response time of the temperature sensor, etc. can be taken into account.

The second measurement of the temperature takes place after a delay time Δt2 has elapsed after the valve current I for the metering valve 16 has been switched off . Due to the delayed measurement of the temperature T2 after the closing of the metering valve 16 at the time t2, the running time of the reducing agent jet, the response time of the temperature sensor, etc. can also be taken into account in addition to the valve closing speed.

The difference ΔT = T1 - T2 is formed from the measured temperature values T1, T2 and then this temperature difference is compared with a system-specific minimum value. If the temperature difference .DELTA.T exceeds the predetermined minimum value, it is recognized via the control unit 17 that a metering pulse has occurred. If the determined temperature difference ΔT remains below the minimum value, a faulty metering device is concluded and this result is entered into a fault memory 19 of the control device 17 and is displayed to the driver of the vehicle equipped with the internal combustion engine 10 optically and acoustically.

If the temperature sensor 18 is sufficiently sensitive and the control unit, in particular the control computer contained therein, has sufficient power, the course of the temperature jump can also be evaluated as a measure of the length of the metering pulse, and thus the amount of reducing agent injected can be inferred at constant pressure. For example, values for the length of the metering pulse or the amount injected can be stored in a map of a memory 20 of the control unit 17 as a function of the temperature difference ΔT.

By using the output signal of the anyway Temperature measurement in the exhaust tract of the internal combustion engine arranged and to trigger the dosing of the reducing agent The temperature sensor used results in a cost Favorable way, the dosing device, especially that Monitor the metering valve for its operability.

If the NO _x reduction system is equipped with a heated device for mixing the exhaust gas with the reducing agent, in order to ensure the best possible mixing and an early start of the metering, the temperature measurement on the part which is used to regulate the heating output can also be carried out. or the measurement of the ohmic heating resistance can be used as a measure of the temperature for monitoring the dosage.

FIG. 3 schematically shows the construction of such an exhaust system, which, in contrast to the system according to FIG. 1, additionally has an electrically heated gas mixer 21 upstream of the SCR catalytic converter 13 . The remaining components of FIG. 3 are identical to the components of FIG. 1 and are therefore provided with the same reference symbols. The gas mixer 21 has a temperature sensor, which is not explicitly shown, for regulating the heating power of the electric heating device. The output signal of this temperature sensor can be used analogously to the manner described with reference to FIG. 1 for checking the metering valve 16 .

Alternatively, the change in the electrical Wi of the heating device during the dosing process as a measure of the temperature change for monitoring the dose tion can be used.

The upper part of Fig. 4 shows the typical course of the electrical resistance of the heating device of the gas mixer with reducing agent metering and the lower part of Fig. 4 shows the time course of the drive current for the Doier valve.

In contrast to the exemplary embodiment according to FIGS. 1 and 2, in this case, at the specified times t1 + Δt1 and t2 + Δt2, not temperature values but rather values for the ohmic resistance of the heating device are detected. The procedure for evaluating the measured resistance values is in accordance with the procedure for evaluating the temperature values as described above. Depending on the resistance difference ΔR, values for the length of the metering pulse or the injected amount can then be stored in the memory 20 .

If the heating device of the gas mixer 21 is equipped with a rapid temperature control, which immediately increases the heating power when the temperature sensor cools down due to the addition of the dosing agent, i.e. the heating current increases and thus results in an approximately constant heating resistance, the heating power or the heating current can be used as a measure of the Evaporation heat as a result of the injection pulse can be used analogously to the temperature measurement.

Claims (13)

1. A method for monitoring the reducing agent metering in a diesel internal combustion engine or a diesel combustion system, the temperature of the exhaust gas being detected by means of a temperature sensor and above a limit temperature of the exhaust gas by means of a metering device, a reducing agent at a point upstream of an SCR catalytic converter arranged in the exhaust gas stream Pressure is supplied, characterized in that

• 1. the reducing agent is supplied in the immediate vicinity of the temperature sensor ( 18 ) so that at least part of the reducing agent reaches the temperature sensor ( 18 ),
• 2. the temperature curve (T) which arises due to the reducing agent metering by evaporation heat by means of the temperature sensor ( 18 ) and
• 3. From the temperature profile (T) a statement about the functionality of the metering device ( 14 , 15 , 16 ) is made.

2. The method according to claim 1, characterized in that

• 1. that the temperature values (T1, T2) are recorded before and after the addition of the reducing agent,
• 2. a temperature difference (ΔT) is formed from these temperature values (T1, T2),
• 3. the temperature difference (ΔT) is compared with a predetermined threshold value and
• 4. When the threshold value is exceeded, a reduction in the reducing agent is detected.

3. The method according to claim 2, characterized in that the Temperature value (T1) only after a delay time has elapsed (Δt1) after the start of dosing and the temperature value (T2) only after a delay time (Δt2) after the end of the Dosage is recorded.   4. The method according to any one of the preceding claims, characterized characterized in that the temperature curve (T) during the Thursday siergangses as a measure of the length of the dosing process evaluates and based on this assuming constant injection pressure when adding the reducing agent to the injected Amount of reducing agent is closed. 5. The method according to claim 4, characterized in that in dependence on the temperature difference (ΔT) values for the length of the metering pulse or the injected reducing agent quantities are stored in a map of a memory ( 20 ) of a control unit ( 17 ) controlling the metering operation. 6. A method for monitoring the reducing agent metering in a diesel internal combustion engine or a diesel combustion system, the temperature of the exhaust gas being detected by means of a temperature sensor and above a limit temperature of the exhaust gas by means of a metering device, a reducing agent at a point upstream of an SCR catalytic converter arranged in the exhaust gas stream and one for mixing the gas with the reducing agent serving, electrically heated th gas mixer is supplied under pressure, characterized in that

• 1. the reducing agent is supplied in the immediate vicinity of the electrical heating device of the gas mixer ( 21 ),
• 2. the electrical resistance (R) of the heating device which arises during the reducing agent metering due to the heat of vaporization and
• 3. From the resistance curve (R), a statement about the functionality of the metering device ( 14 , 15 , 16 ) is made.

7. The method according to claim 6, characterized in

• 1. that the resistance values (R1, R2) are recorded before and after the addition of the reducing agent,
• 2. a resistance difference (ΔR) is formed from these resistance values (R1, R2),
• 3. the resistance difference (ΔR) is compared with a predetermined threshold value and
• 4. When the threshold value is exceeded, a reduction in the reducing agent is detected.

8. The method according to claim 7, characterized in that the Resistance value (R1) only after a delay time has elapsed (Δt1) after the start of dosing and the resistance value (R2) only after a delay time (Δt2) after the end of the Dosage is recorded. 9. The method according to claim 3 or 8, characterized in that the delay time (.DELTA.t1, .DELTA.t2) is selected depending on at least one of the sizes valve reaction time of a metering valve spraying the reducing agent ( 16 ), running time of the reducing agent, response time of the temperature sensor ( 18 ) . 10. The method according to any one of the preceding claims 6 to 9, characterized in that the resistance curve (R) during of the dosing process as a measure of the length of the dosing process evaluated and based on this assuming constant on injection pressure when adding the reducing agent to the injected amount of reducing agent is closed. 11. The method according to claim 10, characterized in that, depending on the difference in resistance (ΔR), values for the length of the metering pulse or the injected reducing agent quantities are stored in a map of a memory ( 20 ) of a control unit ( 17 ) controlling the metering process. 12. A method for monitoring the reducing agent dosage in a diesel internal combustion engine or a diesel combustion system, the temperature of the exhaust gas being detected by means of a temperature sensor and above a limit temperature of the exhaust gas by means of a metering device, a reducing agent at a location upstream of an SCR catalytic converter arranged in the exhaust gas stream and one for mixing the gas with the reducing agent serving, electrically heated th gas mixer is supplied under pressure, characterized in that

• 1. the reducing agent is supplied in the immediate vicinity of the electrical heating device of the gas mixer ( 21 ),
• 2. the heating current of the electrical heating device which is established during the reducing agent metering due to the heat of vaporization and
• 3. From the course of the electric heating current, a statement about the functionality of the metering device ( 14 , 15 , 16 ) is made.

13. The method according to claim 12, characterized in that

• 1. that the values for the heating current are recorded before and after the addition of the reducing agent,
• 2. a difference is formed from these values and compared with a predetermined threshold value and
• 3. if the reducing agent is dosed if the reducing agent has been detected.