Method for diagnosing an exhaust gas cleaning system of a...

Details Method for diagnosing an exhaust gas cleaning system of a... Method for diagnosing an exhaust gas cleaning system of a...

2002-10-09

2004-10-05

Tran, Binh Q. (Department: 3748)

Power plants

Internal combustion engine with treatment or handling of...

Having sensor or indicator of malfunction, unsafeness, or...

C060S274000, C060S276000, C060S285000

Reexamination Certificate

active

06799419

ABSTRACT:

BACKGROUND OF INVENTION
The invention relates to a method for diagnosing an exhaust gas cleaning system in the exhaust section of a lambda-controlled internal combustion engine having a 3-way catalytic converter, a binary pre-catalyst lambda sensor connected upstream of the catalytic converter, and a post-catalyst lambda sensor connected downstream of the catalytic converter.
In an exhaust gas cleaning system with two lambda sensors, a pre-catalyst lambda sensor upstream of the catalytic converter is used as a measuring sensor. A post-catalyst lambda sensor downstream of the catalytic converter serves as a monitoring sensor for monitoring and compensating for a change in the static or dynamic properties of the pre-catalyst lambda sensor which would lead to an increase in emissions. Usually, both lambda sensors have a two-point characteristic, and the voltage signal which they emit is dependent on the oxygen content in the exhaust gas. The oxygen content in the exhaust gas is in turn dependent on the mix which has been fed to the internal combustion engine. If the mix is lean (lambda>1), the output voltage from a binary lambda sensor is usually below 100 mV, changes almost as an abrupt jump in the region of lambda=1 and, when the mix is rich (lambda<1), reaches over 0.7 V; this is known as a two-point characteristic.
The dynamic and static properties of the pre-catalyst lambda sensor are altered by sensor aging and poisoning. As a result, the control position of the lambda control is shifted. For example, phosphorus poisoning may lead to an asymmetrical change in the sensor response time and therefore to a lean shift in the sensor control out of the optimum lambda range for the catalytic conversion. As a result, by way of example, the NO
x
emissions may rise beyond a permitted limit. The post-catalyst lambda sensor is used as a monitoring sensor for monitoring the catalytic conversion and for fine control of the mix in order always to be able to maintain the lambda value which is most favorable for conversion. Use is made of the fact that the two-point characteristic of the post-catalyst lambda sensor, on account of the conversion capacity, which also has a damping effect, of the catalytic converter, approximately changes into a linear characteristic within a very limited lambda range. This method, which is usually known as trimming or guide control, is known, for example, from DE 35 00 594 C2.
The prior art has disclosed numerous methods for diagnosing or checking a catalytic converter, for example DE 41 28 823 A1, which determines the oxygen storage capacity of a 3-way catalytic converter by recording the time required to empty or fill the catalytic converter with oxygen and calculating the quantity of oxygen from this time. For this method, a lambda sensor with wide-band characteristics, i.e. the signal of which changes proportionally to the lambda value, is imperative upstream of the catalytic converter.
However, the known methods have the drawback that, if the pre-catalyst lambda sensor is defective, a defective catalytic converter is often diagnosed, even though unacceptable levels of emissions are not yet being discharged. According to the prior art, it is not possible to differentiate between a catalytic converter defect and a failure of the pre-catalyst lambda sensor. Furthermore, the high oxygen loading/discharge, which is required for diagnosis according to the prior art, often leads to an undesirable level of pollutant emissions, since the catalytic converter is then no longer operated in its optimum range. Finally, wide-band lambda sensors are relatively expensive. Methods which are based on less expensive binary lambda sensors, i.e. lambda sensors with a two-point characteristic, have not hitherto been worthy of comparison with regard to their diagnosis capacity.
SUMMARY OF THE INVENTION
It is an object of the present invention to provide a method for diagnosing an exhaust gas cleaning system of a lambda-controlled internal combustion engine which does not necessarily require the use of a binary lambda sensor and which makes it possible to differentiate between a defect in the pre-catalyst lambda sensor and a failure of the catalytic converter.
This object is achieved by the invention wherein the oxygen storage capacity of the catalytic converter, which is a measure of its conversion capacity, is used to diagnose the exhaust gas cleaning system. The catalytic converter is subjected to a load which is brought about by fluctuation of the fuel/air ratio about the stoichiometric point and which is greater than the operating load which occurs with standard binary lambda control. However, a certain maximum catalytic converter load is not exceeded. The load is predetermined by influencing the oscillation of the fuel/air ratio and therefore the signal from the pre-catalyst lambda sensor. For diagnosis, the oscillation characteristic of the signal from the post-catalyst lambda sensor is evaluated. The fluctuating load is adsorbed to a greater or lesser extent in the catalytic converter depending on the oxygen storage capacity of the catalytic converter. The oscillation of the signal from the post-catalyst lambda sensor therefore differs depending on the oxygen storage capacity of the catalytic converter. Measurements carried out on a catalytic converter which has just fallen below the predetermined oxygen storage capacity, and therefore the desired conversion capacities, can be used to determine a desired range for the oscillation characteristic of the signal from the post-catalyst lambda sensor. A catalytic converter of this type is usually known as a limit catalytic converter.
If the oscillation is greater, i.e. the amplitude or included area is larger, the diagnosed catalytic converter is worse than the limit catalytic converter.
In a preferred embodiment of the method, the loading of the catalytic converter is set by controlling the fluctuation of the fuel/air ratio in such a way that the oscillation of the signal from the pre-catalyst lambda sensor includes a certain minimum area. The oxygen mass mO2 which is introduced into the catalytic converter within a half period of the oscillation can be calculated according to the following equation:
m
O2=21%(lambda−1)/lambda
MAF T
½
where MAF is the mass flow of fresh gas sucked in. mO2 is the oxygen mass which is fed to the catalytic converter during the half period of the lambda control in which the mix is lean. By varying the duration of the half period T½, it is therefore possible to set the catalytic converter loading, i.e. the quantity of oxygen introduced into the catalytic converter. By correspondingly varying the duration of the other (rich) half period, it is possible to vary the catalytic converter load and nevertheless to keep the mix stoichiometric on average. The terms “loading” and “load” are therefore used interchangeably.
In a preferred embodiment of the invention, with a binary lambda control the P-jump delay time is adjusted, with the result that T½ changes. To ensure that the internal combustion engine is nevertheless on average supplied with a stoichiometric mix, the P-jump delay time must vary in the same way both for the jump from lean to rich and for the jump from rich to lean. The catalytic converter load which is predetermined in this manner can be oriented to the emission limits which are to be checked.
Stipulating the loading has the advantage of being significantly less sensitive to load/rotational speed variations than known methods. Particularly at low engine loads or rotational speeds, good diagnosis of the catalytic converter is still possible.
The trimming control likewise has an effect on the P-jump delay time, but only on the delay time for one jump, either from lean to rich or from rich to lean. This different or one-sided change in the P-jump delay time means that the trimming control compensates for age-related changes in the pre-catalyst lambda sensor. Changes of this type generally lead to a shift in the lambda=1 working point of

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