EP1336743A2 - Method for forcing excitation of a lambda control system - Google Patents

Abstract

The forced stimulation method has 2 different weak/rich amplitude values superimposed on the lambda required value during successive sets of exhaust packets, the regulation device determining the second amplitude value and a component of the second exhaust packet set, so that the signal values provided by the lambda probe on the downstream side of the catalyzer are altered.

Description

The present invention relates to a method for positive excitation with a lambda control for an internal combustion engine a catalyst, upstream and downstream of it arranged lambda probes and a control device.

New guidelines for exhaust gas reduction make an increased one Exhaust gas purification required. In the article by Cornelius et al. "The Role of Oxygen Storage in NO Conversion in Automotive Catalysts "it is described that by a Forced excitation a better exhaust gas conversion is achieved. In the case of forced excitation, a lambda setpoint becomes a rich / lean amplitude superimposed. The well-known forced stimulation is symmetrical to a lambda setpoint.

DE 43 44 892 C2 describes a control of the air / fuel mixture known, forcibly regardless of the operating state oscillates between enriched and lean states, to increase the cleaning efficiency of the catalyst.

DE 198 44 994 A1 describes a method for diagnosing a steady lambda sensor known. In the process, the Setpoint for the lambda control through periodic forced excitations imprinted and the system behavior of the lambda control circuit reproduced using a model. The amplitude gain of model and system are compared with each other and depending on the result of the comparison of the model parameters adapted. Is the change in the model parameter above a threshold, the lambda probe is considered defective classified. The superimposed amplitude is symmetrical to the lambda setpoint and fat and lean areas are the same from.

DE 195 16 239 describes a method for parameterizing a Lambda control device known. Approach to parameterization is that the transfer function of the lambda control system as a series connection of two delay elements first order and a dead time element in the lamda control loop can be displayed. The air number average is controlled by a PID controller. The determination of the route parameters takes place depending on a probe output signal a linear lambda probe.

In the case of a lambda control, it is generally assumed that an optimal conversion with a signal value of the downstream dependent on a catalytic converter arranged lambda probe is predetermined from the operating point. Since the conversion of the Depending on its history, it can when regulating to slowly drift away the conversion rate come without this through the signal value of the downstream catalyst is displayed.

The invention has for its object a forced excitation To provide a reliable with simple means Avoids deterioration of the exhaust gas conversion.

According to the invention, the object is achieved by a method with the Features solved from claim 1. Advantageous configurations form the subject of the subclaims.

The method according to the invention is based on a so-called Fine metering of the exhaust gas composition. For this be a lambda setpoint for a positive excitation for a first one Number of exhaust gas packets a first amplitude and for a second number of exhaust gas packs at least two different ones second amplitude values superimposed. The control device determines one of the second amplitude values and an associated one Share of the second exhaust gas packets such that the signal values due to the downstream lambda sensor change these exhaust gas packages. A reversal of the Signal values achieved. With the help of the forced stimulation the inventive method a good optimization of the exhaust gases reached. At the same time, the additional second Amplitude value a targeted influencing of the signal values Lambda probe located downstream of the catalyst. In the method according to the invention, a targeted Stimulation of the downstream of the catalyst Lambda probe, the creeping drift away the conversion rate prevented.

The direction reversal of the signal values is preferably carried out by Addition or removal of rich or lean exhaust gas packages. An operating point-dependent reversal of direction is brought about, which are in regular or irregular timings Repeat intervals. By the number of lean exhaust packets is varied, the control device remains Freedom, the number and the lambda values of the remaining forced stimulation depending on the load and speed depending on the operating point to determine.

The one about the first number and the second number of exhaust gas packages determined lambda value corresponds to the lambda setpoint. In this case, both second amplitude values are preferably lean.

In a preferred embodiment of the method according to the invention is the first and second number of exhaust packs Multiple of the number of cylinders in an exhaust system with a Catalyst are provided. The advantage is that Cylinder inequalities in the lambda values and those of the exhaust gas composition be averaged out over the period.

Accuracy in forced excitation and conversion the signal values of the downstream catalyst over the first and the averaged second number of exhaust gas packets. For those so averaged Signal values are checked for a reversal of direction of the signal values achieved by one of the second amplitude values becomes.

Fig. 1:

die Amplitudenwerte für die Zwangsanregung und

Fig. 2:

ein schematisches Ablaufbild zur Bestimmung der Amplitudenwerte.

The method according to the invention is described in more detail below using an exemplary embodiment. It shows:

Fig. 1:

the amplitude values for the forced excitation and

Fig. 2:

a schematic flow chart for determining the amplitude values.

1 shows the amplitudes of the forced excitation according to one Embodiment of the method according to the invention. In Fig. 1 is the course of the DELTA_LAMBDA_WERTE plotted that can be added to a lambda setpoint. The excitation amplitude is plotted against time in milliseconds. Curve 10 shows the course of the amplitude values in the conventional one Forced excitation. Curve 10 has approximately a sinusoidal shape Course in which the fat / lean amplitudes over ignore rising or falling edges. In the illustrated For example, the known forced excitation has an excitation amplitude of approximately 0.030 and a period approximately 850 ms.

The amplitude profile according to the method according to the invention is shown as an example in curve 12. In a first Period 14, the amplitudes 16 and 18 for the lean Suggestion given. As an alternative to using two different amplitude values can also be different Numbers of exhaust gas packs can be used. In the illustrated For example, the amplitude value 18 is larger, i.e. the resulting lambda is leaner than the amplitude value 16. In the subsequent period 20 a third amplitude value 22 subtracted from the desired lambda value. The lambda setpoint is less rich than one of the two amplitude values 16 and 18. The duration of the excitation 14 and 20 are approximate in the illustrated embodiment of equal length.

The sequence of the three amplitude values 16, 18 and 22 is repeated the duration of the amplitude values 16 and 18 varies. In the example shown, the duration of the lean amplitude 18 shortened in the three successive periods.

The duration of the amplitude values 18 is determined by observing the Determined by Kat probe signal. This will be an effective one Conversion through the catalyst possible without that the so-called "falling asleep" of the catalyst or a Breakthrough oxygen occurs.

2 shows the method steps in a schematic block diagram to determine the excitation amplitude. As Input variables 24 and 26 are the current values for the Speed and load on. The input values 24 and 26 are each on the calculation modules 28 and 30. Calculated here Module 28 the value for the first lean excitation amplitude 16 (IP_DE_LAMB_SP_AFL). The second calculation module 30 calculates the value for the excitation amplitude 22 in phase the rich lambda values (IP_DE_LAMB_SP_AFR). The module 32 calculates the value for the second lean amplitude 18 (IP_DELTA_LAMB_AFL_COR). In addition to being dependent on Load and speed depend on the calculation of the second lean Amplitude from the output signal of an exhaust gas control device 34 from.

The output signals of the units 28, 30, 32 are at one Switch 36 on. The switch 36 switches depending on that Output signal of the exhaust gas control device 34 one of the adjacent Input signals as lambda output signal 38 further.

The is another input variable for the forced excitation Signal value of the signal values 40 of the lambda probe downstream from the catalyst, the so-called post-cat signal. Dependent The input variable 40 is used in a module 42 Determines the number of segments in which the amplitude value is 18 should be applied (IP_SEG_NR_AFL_COR). When specifying the semgent time 44 becomes an even multiple of the number of cylinders or a cylinder bank selected. On the exhaust control device 34 are also the constants for the number of lean Segments (C_SEG_NR_AFL) and the bold segments (C_SEG_NR_AFR). The sum of the segment numbers determines the Frequency of forced stimulation, the duration with fat and lean amplitude can be different.

In the model 46 the development of the catalyst signal 40 monitors. Monitoring takes place, for example, whether there are deviations in the catalyst signal 40 over several Periods occur. The catalyst signal can also 40 are monitored for a threshold value. The initial size the monitoring unit 46 is located on the exhaust gas control device 34 so that if there is a deviation in the catalyst signal 40 the control device 34 correspondingly the three amplitude values can switch.

The output signal 48 of the exhaust gas control device 34 is also present on the module 32 so that the determination of the amplitude value 18 depending on the catalyst signal 40 can.

For example, after a full grease due to a Acceleration of the post-cat probe signal level (VLS_DOWN) on. An optimum for the conversion is due to a regulation the signal values of the downstream catalyst depending on the history of the cat load, so-called Memory effect. For example, after a very fat load the possibility that with signal values of the catalyst emissions deterioration occurs under normal operating conditions do not occur. With this effect you can abrupt NOx breakthroughs can occur. With one in Operating point dependent constant value control for the lambda values, this memory effect is not taken into account, nor can account for a slow drift in conversion rates be worn. With the forced dosing according to the invention, in which the exhaust gas composition is finely metered, becomes the signal of the downstream catalyst stimulated regularly. Sinks from one, for example Evaluation cycle to the next the signal value of the downstream lying catalyst, so the oxygen content in the exhaust gas reduced. There are increasing changes between the evaluation cycles on, the oxygen content in the exhaust gas is increased. is over a number of steps changing the downstream If the lambda probe values are less than zero, the value will exceed a reversal of the signal values for a predetermined number given by a changed exhaust gas composition and implemented. Once this level has risen, be subsequently the signal values are lowered in the same way, until a predetermined minimum value is reached. This The minimum value is increased by targeted fine exhaust gas metering and crossed down and brought back to phase avoid drifting away of the signal values.

Claims (8)

Method for the positive excitation of a lambda control for an internal combustion engine with a catalytic converter, a lambda probe arranged upstream and downstream thereof and a control device, which has the following method steps: A first amplitude value (22) is superimposed on a lambda target value for a first number of exhaust gas packets and at least one second amplitude value (16) for a second number of exhaust gas packets, the control device determines one of the second amplitude values (18) and a portion of the second exhaust gas packets in such a way that the signal values of the lambda probe located downstream change due to these exhaust gas packets. Method according to claim 1, characterized in that at least two different second amplitude values (16, 18) are provided. Method according to Claim 1, characterized in that an operation-dependent, repetitive reversal of the direction of the signal values of the lambda probe arranged downstream is achieved by the exhaust gas packets with the one of the two amplitude values. A method according to claim 3, characterized in that the direction reversal of the signal values takes place by adding or removing rich or lean exhaust gas packets. Method according to one of Claims 1 to 4, characterized in that the lambda values, averaged over the first and second number of exhaust gas packets, correspond to a lambda target value. Method according to one of claims 1 to 5, characterized in that the excitation amplitudes (16, 18) of the second number of exhaust gas packets are lean. Method according to one of claims 1 to 6, characterized in that the number of first and second exhaust gas packets are a multiple of the number of cylinders which are provided in an exhaust line using an associated catalytic converter. Method according to one of claims 1 to 7, characterized in that the signal values of the lambda probe arranged downstream of the catalytic converter are averaged over the number of the first and second exhaust gas packets.

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