Method of detecting an emulator for an SCR catalytic converter system

Abstract

The invention concerns a method (200) of detecting an emulator for an SCR catalytic converter system (10) with the following steps: operating the SCR catalytic converter system (10) in a test state; and measuring a test variable of the SCR catalytic converter system (10); and deciding whether the test variable is behaving as for an SCR catalytic converter system (10) with or without an emulator.

Claims

1. A method (200) of detecting an emulator for an SCR catalytic converter system (10), the method comprising: operating, via a computer, the SCR catalytic converter system (10) in a test state by setting a specified time profile of a set point pump pressure value (100); measuring, via the computer, a time profile of a pump pressure signal (120) in the SCR catalytic converter system (10) as a test variable of the SCR catalytic converter system (10); and deciding, via the computer, whether the test variable is behaving as for an SCR catalytic converter system (10) operating with or without an emulator based on comparing the specified time profile and the measured time profile.

2. The method according to claim 1, wherein the operation of the SCR catalytic converter system (10) in the test state is carried out by switching off a control unit of either a pump (32) or a metering module (17) of the SCR catalytic converter system (10); and the test variable of the SCR catalytic converter system (10) is a profile of the pump pressure signal (120) in the SCR catalytic converter system; wherein if the pump pressure signal (120) is approximately equal to the ambient pressure, it is decided that the test variable is behaving as for an SCR catalytic converter system (10) without an emulator, and, if the pump pressure signal (120) is not approximately equal to the ambient pressure, it is decided that the test variable is behaving as for an SCR catalytic converter system (10) with an emulator.

3. A method (200) of detecting an emulator for an SCR catalytic converter system (10), the method comprising: determining a Fourier component of a Fourier transform (140) of a pump pressure profile at a specified frequency if a control unit of the SCR catalytic converter system (10) receives a signal that an oscillation-inducing component of the SCR catalytic converter system (10) is operating; determining a Fourier component of a Fourier transform (140) of a pump pressure profile at a specified frequency if a control unit of the SCR catalytic converter system (10) receives a signal that the oscillation-inducing component of the SCR catalytic converter system (10) is not operating; deciding that an emulator is being used if on the one hand the Fourier component of the Fourier transform (140) of the pump pressure profile at the specified frequency for the case in which the control unit of the SCR catalytic converter system (10) receives a signal that the oscillation-inducing component of the SCR catalytic converter system (10) is operating, is less than or equal to the Fourier component of the Fourier transform (140) of the pump pressure profile at the specified frequency for the case in which the control unit of the SCR catalytic converter system (10) is not receiving a signal that the oscillation-inducing component of the SCR catalytic converter system (10) is operating, and if on the other hand the oscillation-inducing component is operating properly.

4. The method according to claim 3, wherein the oscillation-inducing component of the SCR catalytic converter system (10) is a pump (32) or a metering module (17).

5. The method according to claim 3, wherein the specified frequency is a frequency that originates from the oscillation-inducing component.

6. A non-transitory, computer-readable medium containing computer-readable instructions that when executed by a computer cause the computer to detect an emulator for an SCR catalytic converter system (10) by determining a Fourier component of a Fourier transform (140) of a pump pressure profile at a specified frequency if a control unit of the SCR catalytic converter system (10) receives a signal that an oscillation-inducing component of the SCR catalytic converter system (10) is operating; determining a Fourier component of the Fourier transform (140) of a pump pressure profile at a specified frequency if a control unit of the SCR catalytic converter system (10) receives a signal that the oscillation-inducing component of the SCR catalytic converter system (10) is not operating; deciding that an emulator is being used if on the one hand the Fourier component of the Fourier transform (140) of the pump pressure profile at the specified frequency for the case in which the control unit of the SCR catalytic converter system (10) receives a signal that the oscillation-inducing component of the SCR catalytic converter system (10) is operating, is less than or equal to the Fourier component of the Fourier transform (140) of the pump pressure profile at the specified frequency for the case in which the control unit of the SCR catalytic converter system (10) is not receiving a signal that the oscillation-inducing component of the SCR catalytic converter system (10) is operating, and if on the other hand the oscillation-inducing component is operating properly.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Exemplary embodiments of the invention are represented in the drawings and are described in detail in the subsequent description.

(2) FIG. 1 shows schematically an SCR catalytic converter system with which the method according to an exemplary embodiment of the invention can be carried out.

(3) FIG. 2 shows a time profile of a setpoint pressure value, a pump actuation signal and a pump pressure signal of an SCR catalytic converter system without an emulator.

(4) FIG. 3 shows a time profile of the pump pressure signal after a pump of a transport module or a metering module of the SCR catalytic converter system has been switched off both for the case in which an emulator is emulating the SCR catalytic converter system and for the case in which there is no emulator.

(5) FIG. 4 shows the pump pressure signal and a metering signal of the metering module, which are plotted against time.

(6) FIG. 5 shows two Fourier transforms, respectively of a pump pressure signal for the case in which the metering module is operating, and for the case in which the metering module is not operating.

(7) FIG. 6 shows a Fourier transforms of a pump pressure signal for the case in which the pump of the transport module is operating.

(8) FIG. 7 shows a schematic flow chart of a method according to an exemplary embodiment of the invention.

DETAILED DESCRIPTION

(9) An SCR catalytic converter system 10 with a metering device for metering urea-water solutions 12 into the exhaust system 18 of an internal combustion engine 14 (which is only indicated) of a motor vehicle is represented in FIG. 1. The SCR catalytic converter system 10 is used in a known way for the reduction of nitrogen oxides in the exhaust gas of the internal combustion engine 14 by means of selective catalytic reduction (SCR). For the reduction, urea-water solution 12 is injected as the reduction agent via a metering valve 16 of a metering module 17 into an exhaust system 18 upstream of the SCR catalytic converter 20 and downstream of an oxidation catalytic converter 22.

(10) The urea-water solution 12 is stored in a storage tank 24 that comprises a level sensor 26 and a temperature sensor 28, each of which is connected to a control unit 29. The metering valve 16 of the metering module 17 is supplied with the urea-water solution 12 from the storage tank 24 by means of a transport module 30.

(11) The transport module 30 comprises a transport pump 32 that extracts urea-water solution 12 from the storage tank 24 by means of a suction line 34. The urea-water solution 12 is passed through a pressure line 36 to the metering valve 16 of the metering module 17. The urea-water solution 12 is injected by means of said metering valve 16 into the exhaust system 18 between the internal combustion engine 14 and the SCR catalytic converter 20.

(12) The transport pump 32 and the metering module 17 are controlled by the electronic control unit 29 during this. An exhaust gas temperature sensor 44 and an exhaust gas sensor 46, both of which are disposed downstream of the SCR catalytic converter 20, are also connected to the electronic control unit 29.

(13) Furthermore, the control unit 29 is arranged to operate the SCR catalytic converter system 10, in particular the pump 32 of the transport module 30 and the metering module 17 of the SCR catalytic converter system 10, by means of the method according to the invention.

(14) FIG. 2 shows a time profile of a setpoint pressure value 100, a pump actuation signal 110 and a pump pressure signal 120 of an SCR catalytic converter system 10 without an emulator. The pump pressure signal 120 is provided by a pressure sensor. On the abscissa axis, the time is plotted in seconds. On the ordinate axis, the setpoint pressure value 100 and the pump pressure signal 120 are plotted in millibars, while the pump actuation signal 110 is plotted in relative units, which is indicated by the % character.

(15) After the start of the system, the pump pressure signal 120 increases and approaches the setpoint pressure value 100. Between seconds 50 and 60, the pump pressure signal 120 and the setpoint pressure value 100 have approximately the same value. After second 60, the setpoint pressure value 100 changes multiple times after a certain time and the pump pressure signal 120 follows the setpoint pressure value 100 after a settling period. After the setpoint pressure value 100 has changed in each case, a corresponding adjustment behavior is detected in the pump actuation signal 110, i.e. if the setpoint pressure value 100 has increased, the pump actuation signal 110 increases and if the setpoint pressure value 100 has reduced, the pump actuation signal 110 is smaller.

(16) FIG. 3 shows a time profile of the pump pressure signal 120 after a pump 32 of a transport module 30 or a metering module 17 of the SCR catalytic converter system 10 has been switched off, both for the case in which an emulator is emulating the SCR catalytic converter system 10 and for the case in which there is no emulator. At the point in time ti, the control unit switches the pump 32 or the metering module 17 off. The pump pressure signal 120 time behavior does not change for the case in which an emulator is emulating the SCR catalytic converter system 10; this is the pump pressure signal 120, which is characterized by the letter E. On the other hand, the pump pressure signal 120 decreases to the ambient pressure for the case in which there is no emulator; this is the pump pressure signal 120, which is characterized by the letter N.

(17) FIG. 4 shows the pump pressure signal 120 in millibars and a metering signal 130 of the metering module 17 in relative units, which is plotted against the time measured in seconds. After the metering signal 130 has been switched on at second 725, larger fluctuations than before can be seen in the pump pressure signal 120.

(18) FIG. 5 shows two Fourier transforms 140, respectively of a pump pressure signal 120 for the case in which the metering module 17 is operating, see left part of the figure, and for the case in which the metering module 17 is not operating, see right part of the figure. In the right part of the figure, which shows the case in which the metering module 17 is not operating, the Fourier transform 140 only comprises components at very low frequencies below 1 Hertz. On the other hand, the left part of the figure shows, in addition to the same components around 1 Hertz as in the right part of the figure, further significantly visible Fourier components at a frequency of 2 Hz and multiples thereof. If the control unit receives a signal that the metering module 17 is operating and at the same time there are no Fourier components as in the left parts of the figure in the Fourier transform 140 of the pump pressure signal 120, then there is the suspicion that an emulator is present.

(19) FIG. 6 shows a Fourier transform 140 of a pump pressure signal 120 for the case in which the pump 32 of the transport module 30 is operating. The Fourier components at approx. 18 Hz correspond to the rotation frequency of the motor of the pump 32. The Fourier components at approx. 36 Hz correspond to twice the rotation frequency of the motor of the pump 32. As the metering module 17 was operating at the same time during said measurement, the Fourier transform 140 also shows Fourier components at multiples of the operating frequency of the metering module 17, which corresponds to approximately 2 Hz.

(20) FIG. 7 shows a flow chart of a method 200 of detecting an emulator for an SCR catalytic converter system 10. The method 200 starts at step 210. In step 210 a pump pressure signal 120 is transformed by means of a discrete Fourier transformation into a Fourier transform 140. In the subsequent step 220, a query is made as to whether an oscillation-inducing component of the SCR catalytic converter system was operating at the point in time of creating the Fourier transform 140. If this was the case, which is illustrated with a tick, the method 200 proceeds at step 230. If this was not the case, which is illustrated with a cross, the method 200 proceeds at step 240.

(21) In step 230, the largest detected amplitude of the Fourier components at the specified frequency is stored as value B. The specified frequency depends on the oscillation-inducing component of the SCR catalytic converter system. If this is a metering module 17, then the value of the specified frequency is about 2 Hz; if the oscillation-inducing component is a motor of the pump 32 of the transport module 30, then the value of the specified frequency is about 18 Hz.

(22) In step 240, the largest detected amplitude of the Fourier components at the specified frequency is stored as the value A.

(23) The method continues from both step 230 and from step 240 at step 250, in which a query is made as to whether the value A equals the value B. If this is not the case, then the method continues with step 260. If this is the case, then the method continues with step 270.

(24) In step 260, it is determined that no emulator has been detected. In the subsequent step, the method returns to step 210 and starts again from there.

(25) If the method continues with step 270, i.e. for the case in which the value A equals the value B, the method 200 has detected no difference in the Fourier component for the case in which the control unit receives the signal that the oscillation-inducing component is operating and for the case in which the control unit receives the signal that the oscillation-inducing component is not operating. This can only mean that the oscillation-inducing component is not producing oscillations. The values A and B are seen as equal if the magnitude of the difference of the two Fourier components is less than 0.5 Hz.

(26) In step 270, a query is made as to whether the component that is producing equality has a fault. If this is the case, then the method continues with step 280. If this is not the case, then the method continues with step 290.

(27) In step 280, it is detected that there is a fault in the oscillation-inducing component, for which reason the values A and B are of equal magnitude. In the subsequent step the method continues with step 260, in which it is determined that no emulator has been detected.

(28) In step 290, it is determined that an emulator has been detected.