The present disclosure relates to internal combustion engines. Various embodiments may include methods for operating an internal combustion engine, in the exhaust-gas tract of which a 3-way catalytic converter with closed-loop lambda control is arranged.
The German patent application 10 2017 218 327.6 does not constitute a prior publication. Therein, a lambda setpoint value upstream of a 3-way catalytic converter, which is of importance for the closed-loop emissions control, is determined or established by combined measurement of a lambda value and of an NH3 value by means of a NOx sensor with integrated lambda probe downstream of the 3-way catalytic converter. By precisely establishing this lambda setpoint value upstream of the 3-way catalytic converter, it is possible to keep lambda downstream of the catalytic converter in a precisely defined range, in order to minimize the NOx and CO2/HC emissions. Below a threshold value of the electrical signal (binary signal) which represents the lambda value, the lambda setpoint value upstream of the 3-way catalytic converter is determined by the difference between the setpoint value of the electrical signal for the lambda value and the measured lambda value. Above a threshold value of the corresponding lambda signal, the lambda setpoint value upstream of the catalytic converter is however determined in a different way, specifically by means of the difference between an NH3 setpoint value of the NOx sensor and the measured NH3 signal of the NOx sensor. The NH3 quantity occurring downstream of the 3-way catalytic converter is thus used for closed-loop control purposes.
The teachings of the present disclosure describe methods for operating an internal combustion engine with a 3-way catalytic converter and closed-loop lambda control, in which method the closed-loop lambda control can be performed particularly quickly and precisely. For example, some embodiments include a method comprising: arranging a binary lambda sensor and a NOx and/or NH3 sensor downstream of the 3-way catalytic converter; when the internal combustion engine is run for the first time, setting a lambda setpoint value for the closed-loop control by means of the binary lambda sensor to an initial value; during the closed-loop lambda control with this setpoint value, measuring the NH3 value in the exhaust gas downstream of the 3-way catalytic converter by means of a NOx signal or NH3 signal from the NOx and NH3 sensor; simultaneously measuring the binary sensor signal from the binary lambda sensor; if the NH3 value lies above a first threshold value, reducing the lambda setpoint value of the binary lambda signal until the NH3 value lies below the first threshold value or the binary sensor signal lies below a second threshold value; recording the corresponding binary sensor signal when the NH3 value passes the first threshold value, for binary sensor signal setpoint value adaptation, as Vbinary-left; and calculating the real lambda setpoint value for the closed-loop lambda control in accordance with the following equation:
V
binary setpoint value
=a×V
binary-left+(1−a)×Vbinary-right (1)
where
Vbinary-left=binary sensor signal at the NH3 limit in the rich direction for setpoint value adaptation
Vbinary-right=binary sensor signal closer to lambda 1 on the rich side
a=weighting factor between 0 and 1.
The teachings herein are explained in detail below with reference to an exemplary embodiment in conjunction with the drawing. The single figure shows, in a diagram, the NOx and binary and linear lambda signals from a NOx sensor with an integrated lambda probe.
In some embodiments, there are separate sensors to be provided as the binary lambda sensor and NOx and/or NH3 sensor. Rather, use may for example also be made of a NOx or NH3 sensor with an integrated lambda probe. The weighting factor a used in equation (1) above, which lies between 0 and 1, may be selected as a function of the air mass flow. In most cases, this weighting factor is selected to be between 0.5 and 0.9. In the case of a large air mass flow, the weighting factor lies closer to 0.9 in order to prevent a NOx breakthrough.
In some embodiments, the closed-loop lambda control can be performed particularly quickly and precisely. Compliance with the desired emissions limits can be ensured over the service life of the internal combustion engine under varying conditions and even with an aged 3-way catalytic converter, with particularly low outlay in terms of calibration.
In some embodiments, the method according to the invention is furthermore distinguished by the fact that, every time the NH3 signal passes the NH3 threshold value (first threshold value) again during the operation of the internal combustion engine, the corresponding binary sensor signal is recorded again and used for a new setpoint value calculation in accordance with equation (1).
In some embodiments, the methods can be used for the setpoint value calculation of a linear lambda sensor signal downstream of the 3-way catalytic converter. Here, in order to achieve the abovementioned object, the teachings herein provides a method for operating an internal combustion engine, in the exhaust-gas tract of which a 3-way catalytic converter with closed-loop lambda control is arranged, which method comprises the following steps: arranging a linear lambda sensor and a NOx and/or NH3 sensor downstream of the 3-way catalytic converter; when the internal combustion engine is run for the first time, setting a lambda setpoint value for the control by means of the linear lambda sensor to an initial value; during the closed-loop lambda control with this setpoint value, measuring the NH3 value in the exhaust gas downstream of the 3-way catalytic converter by means of a NOx signal or NH3 signal from the NOx and/or NH3 sensor; simultaneously measuring a binary sensor signal and a linear sensor signal from the linear lambda sensor; if the NH3 value lies above a first threshold value, increasing the lambda setpoint value of the linear lambda sensor signal until the NH3 value lies below the first threshold value or the binary sensor signal lies below a second threshold value; recording the corresponding linear lambda sensor signal when the NH3 value passes the first threshold value, for linear lambda setpoint value adaptation, as Lambdaleft; if, initially, the binary sensor signal lies below a second threshold value, reducing the lambda setpoint value of the linear lambda sensor signal until the binary lambda signal lies above the second threshold value or the NH3 signal lies above the first threshold value; recording the corresponding linear lambda sensor signal when the binary sensor signal passes the second threshold value, for linear lambda setpoint value adaptation, as Lambdaright; and calculating the real lambda setpoint value in accordance with the following equation:
Lambdasetpoint value=a×Lambdaleft+(1−a)×Lambdaright (2)
where
Lambdaleft=linear lambda sensor signal at the NH3 limit in the rich direction for setpoint value adaptation,
Lambdaright=linear lambda signal closer to lambda 1 on the rich side in the case of a binary sensor signal at the 2nd threshold value,
a=weighting factor between 0 and 1.
It is not necessary for separate sensors to be provided as the linear lambda sensor and NOx and/or NH3 sensor. Rather, use may for example also be made of a NOx or NH3 sensor with an integrated lambda probe. The weighting factor a specified above may be selected as a function of the air mass flow. In most cases, the weighting factor is selected to be between 0.4 and 0.8. In the case of a large air mass flow, the weighting factor lies closer to 0.8 in order to prevent a NOx breakthrough.
In some embodiments, every time the NH3 signal passes the NH3 threshold value (first threshold value) during the operation of the internal combustion engine or the binary sensor signal passes the second threshold value, the corresponding linear lambda sensor signal is recorded again as Lambdaleft or Lambdaright and used for a new setpoint value calculation in accordance with equation (2).
In some embodiments, the initial value of the lambda setpoint value is preferably 750 mV. The first threshold value (NH3 value) is preferably 10 ppm, while the 2nd threshold value (binary sensor signal) is preferably 650 mV.
In some embodiments, the initial value of the lambda setpoint value is preferably 0.997. The first threshold value (NH3 value) is preferably 10 ppm, while the second threshold value (binary signal) is preferably 650 mV.
In some embodiments, for on-board diagnosis, the NOx sensor signal at the lambda setpoint value is used for closed-loop control either with the binary sensor signal or with the linear lambda sensor signal. Here, if the correspondingly obtained value is above a third threshold value, the 3-way catalytic converter is classified as defective.
As discussed above, the teachings herein describe the adaptation of the binary sensor signal or linear lambda sensor signal downstream of the 3-way catalytic converter on the rich side (lambda<1) by means of a NOx or NH3 sensor signal of the NOx and/or NH3 sensor with subsequent determination of the lambda setpoint value either in the form of the binary sensor signal or lambda signal on the basis of the adapted signal for precise closed-loop lambda control downstream of the 3-way catalytic converter.
The figure shows the linear lambda sensor signal downstream of the 3-way catalytic converter on the abscissa and the NOx signal and the binary sensor signal on the ordinate. In the above-described first method variant, the lambda setpoint value for closed-loop control with the binary lambda sensor downstream of the 3-way catalytic converter is set at an initial value of 750 mV. As described above, the NH3 value downstream of the 3-way catalytic converter and the corresponding binary signal are then measured during the closed-loop lambda control with this setpoint value. If, here, the NH3 value lies above 10 ppm, the lambda setpoint value of the binary sensor signal is reduced until the NH3 value lies below 10 ppm or the binary sensor signal lies below 650 mV (second threshold value). The corresponding binary sensor signal when NH3 passes the corresponding threshold value is recorded as Vbinary-left.
Furthermore, the value Vbinary-right is acquired, which corresponds to the binary sensor signal closer to lambda on the rich side and which in this case is 650 mV. Then, from the equation given above, the corresponding binary setpoint value (Vbinary setpoint value) is calculated with the aid of a weighting factor.
In some embodiments, the lambda setpoint value for closed-loop control with a linear lambda sensor downstream of the 3-way catalytic converter is set at an initial value of 0.997. The individual method steps are then carried out in the manner described above, wherein, here, a value of 10 ppm is taken as a basis as the first threshold value (NH3 value) and a value of 650 mV is taken as a basis as the second threshold value (binary signal). The corresponding values Lambdaleft and Lambdaright are ascertained in the manner described above. The lambda setpoint is calculated from equation (2) with the aid of the corresponding weighting factor.
Number | Date | Country | Kind |
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10 2018 206 451.2 | Apr 2018 | DE | national |
This application is a U.S. National Stage Application of International Application No. PCT/EP2019/058769 filed Apr. 8, 2019, which designates the United States of America, and claims priority to DE Application No. 10 2018 206 451.2 filed Apr. 26, 2018, the contents of which are hereby incorporated by reference in their entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2019/058769 | 4/8/2019 | WO | 00 |