EP0153493A2 - Mixture-measuring system for a combustion engine - Google Patents

Abstract

The invention is directed to a mixture metering arrangement for an internal combustion engine with a digital data processor, particularly a microcomputer, the signal processing pattern of which is governed by clock pulses, and with a signal generating means which delivers analog output signals. The signal generating means is responsive to operating parameters of the internal combustion engine and is an exhaust gas sensor responsive to the air ratio Lambda. The exhaust gas sensor is used in a closed-loop control system to influence the air-fuel ratio and changes its output quantity at the air ratio of Lambda=1. In this arrangement, a correcting stage corrects the influence of a delay time (tv) connected with the clocked signal processing on the mixture formation. The delay occurs in the transmission of the change in the output of the sensor. Two methods are indicated for the mode of operation of the correcting stage by means of which a mean value shift of the quantity (FR) influencing the mixture formation is avoided and the concentration of toxic substances in the exhaust gases is minimized. Flowcharts are disclosed to realize the invention by means of a suitably programmed microcomputer.

Description

State of the art

The invention is based on a mixture metering system for an internal combustion engine with a digital computing unit according to the preamble of the main claim. Such a mixture metering system is disclosed for example in DE-OS 31 24 676 (US-SN 38 63 076). Although the known system works satisfactorily in practice, it has been shown, however, that further improvements are possible and necessary because of the high demands on the emission-free nature of the exhaust gas.

Advantages of the invention

The mixture metering system according to the invention for an internal combustion engine with a digital arithmetic unit. With the features of the main claim, however, it makes it possible, regardless of the time of the change in the output variable of a signal generating means in relation to the timed, delayed signal processing of this output signal of the burner to provide an optimal mixture to the engine. In particular, by correcting the influence of a delayed transmission of the change in the output variable of the probe, a low concentration of pollutants in the exhaust gas can be ensured. It has proven to be advantageous to influence the mixture metering as a function of at least the delay time and / or the timing of the digital computing unit.

Further advantages of the invention result in connection with the subclaims from the following description of the exemplary embodiments.

drawing

FIG. 1 shows a rough overview of a mixture metering system with a microcomputer, FIG. 2 shows a block diagram of the mixture metering system according to the invention, and FIG. 3 shows a time diagram to explain the functioning of the mixture metering system in FIG. 2.

Description of the embodiments

The following exemplary embodiments are described in connection with a fuel injection system. The mixture metering system in connection with the correction function according to the invention is, however, independent of the method of metering the mixture, so that the invention can also be used in connection with carburetor systems, for example. The representation of the mixture metering system according to the invention on the basis of a block diagram (FIG. 2) does not limit a practical embodiment to a single possibility of implementation. The implementation by means of a freely programmable computer is therefore problem-free because the invention can be clearly recognized as such and therefore does not cause any problems for a person skilled in the field of electronic mixture metering systems.

Figure 1 shows a schematic overview of a computer-controlled system with the most important components. 11 denotes an arithmetic logic unit which is coupled via a data control and address bus 12 to a memory 13 and to an input / output unit 14. In addition to a signal from a signal generating means, in particular a probe 15, in particular a lambda probe, this unit 14 receives various input variables i _K and outputs various output variables O _K , for example an injection duration for the quantity of fuel to be metered or a signal for the actuator in one Air bypass of a carburetor system.

In Figure 2, an embodiment of the invention is shown as a block diagram. The probe denoted by 15, designed in the present example as an exhaust gas probe, supplies an output variable U _λI to a probe signal evaluation unit 21, which in turn is connected via a time stage 22 to a control device 23 which is preferably designed as a PI controller. Furthermore, the probe signal evaluation unit 21 and the control device 23 are connected to a correction stage 24, to which an output unit 25 is connected. The output unit 25 and the probe signal evaluation unit 21 are supplied in particular with different time cycles of a time cycle unit 26. In addition, a setpoint value _information U _λS is present on the probe signal evaluation unit 21, which represents setpoint value _information for the air-force ratio to be _metered to the internal combustion engine. The signals F _{R of} the output unit 25 and a precontrol unit 28 are fed to a mixture formation unit 27, the precontrol unit 28 input variables via operating parameters of the combustion Engine such as speed, load or temperature and the like processed. The mixture formation unit 27 influences an internal combustion engine 29, the exhaust gas 30 expelled from the internal combustion engine washing around the exhaust gas probe 15 and influencing its output variable U _λI , so that the control loop for mixture formation is closed. It goes without saying that the function of the components of the probe signal evaluation unit 21, time stage 22, control unit 23 as well as correction stage 24 and output unit 25 can also be realized with the aid of a correspondingly programmed microcomputer 31, indicated by dashed lines in FIG. The pilot control by means of the pilot control unit 28 and the timing unit 26 can also be integrated in the microcomputer 31.

Except for the blocks timing unit 26 and correction stage 24 and output unit 25, this arrangement is well known, so that its mode of operation need not be explained in more detail. What is important for the essence of the invention is the fact that, due to the digital, time-clocked data processing, delay times occur in the transmission of the change in the preferably analog output variable U _λI to the mixture formation unit 27 for the superimposed influence on the fuel-air ratio. The time diagrams shown in FIG. 3 serve to explain the problems associated with this, wherein the preferably analog output signal U _{Ai of} the probe 15 for the special case is shown in FIG. 3a that the probe 15 is designed as a (lambda = 1) probe. A low output signal level corresponds to a lean and a high output signal level to a rich air-fuel mixture. This exhaust gas probe output is compared in the probe signal evaluation unit 21 with the target value U _AS and with a counting frequency, the period of which is marked with T, sampled. The corresponding output signal U _{S of} the probe signal evaluation unit 21 is plotted in FIG. 3b. This signal is possibly delayed by a desired time, on the one hand directly to the correction stage 24 and on the other hand via the time stage 22, which essentially serves to shift the average air-fuel ratio, to the control unit 23.

The output signal U _{PI of} the control device 23, which in the present exemplary embodiment has integral behavior for a constant output level of the exhaust gas probe 15 and behavior which is proportional when the output level changes, is plotted in FIG. 3c.

It is now considered state of the art that the output signals of the control device 23 via the output unit 25 influence the mixture formation unit 27, for example multiplicatively by a factor F _R. Since the time period T ₂ between two successive outputs of the output unit 25 generally assumes different values compared to the sampling rate T ₁ , namely in particular larger values, for various programming reasons, as shown in FIGS. 3d and e, time delays between the actual switching operation of the probe can occur and passing this on. Switching occur through the output unit 25. This may result in more or less short-term mean shifts in the output signal F _R , so that, under certain circumstances, a considerable deviation from the air ratio required for a possible catalytic exhaust gas aftertreatment occurs.

To avoid these disadvantages and a resulting high concentration of pollutants, which cannot be reduced by a catalyst either, it is necessary to correct the deviation resulting from this delayed output of size F _R as quickly as possible by an intervention. Correction stage 24 is required for this purpose, the mode of operation of which is explained in more detail below.

• Korrekturwert = (Verzögerungszeit tV/Taktzeit T₂)- Δ Ausgang mit Δ Ausgang = neue Ausgangsgröße - alte Ausggangsgröße berechnet. Um diesen Korrekturwert wird die jeweilige Ausgangsgröße F_R modifiziert (siehe Ablaufplan Seite 8), wobei möglicherweise notwendige Normierungsfaktoren für Δ Ausgang nicht berücksichtigt wurden. Eine Normierung ist im allgemeinen dazu notwendig, die Ausgangsgröße Δ Ausgang in Einheiten der Ausgabegröße F_R umzurechnen.

In FIG. 3d, the quantity F _R output by the correction stage 24 via the output unit 25 in the time cycle T _{2 is} plotted. The delay time occurring in the transmission of the change in the output variable of the exhaust gas probe 15 due to the different processing times in the microcomputer is identified by t _V. The signal curve, which would occur without the action of the output unit 25 and the correction stage 24, is indicated by dashed lines. It can be seen from this figure that, due to the delayed output, a shift in the mean value of the output signal F _R occurs since the area ratio changes for areas above and below the dashed line entered at F _r = 1. This leads at least for a short time to a change in the air-fuel ratio supplied to the internal combustion engine. To avoid this shift in the mean value, two options are now proposed. In both cases, the delay time, which results from the difference between the change in the output variable of the exhaust gas probe and the actual output (see FIG. 3b in conjunction with 3d), is set in relation to the cycle time T ₂ . To determine a correction value according to the first method, a multiplication of this value by the quantity Δ output is provided, which, of course, normalized in a suitable manner, results from the difference between the new output variable and the old output variable, for example of the probe signal converter unit 21. In the present special case, the ratio of delay time to cycle time T ₂ is approximately 0.75 and the value Δ output from FIG. 2b is (-1), so that the correction value amounts to (-0.75) arbitrary units (based on the scale of FIG. 3c). The next time the probe is switched, the same conditions are present, but with the opposite sign for the output, that this results in a correction value of (+0.75) arbitrary units. The correction value is thus based on the calculation rule:

• Correction value = (delay time tV / cycle time T ₂ ) - Δ output with Δ output = new output variable - old output variable calculated. The respective output variable F _{R is} modified by this correction value (see flowchart on page 8), whereby any necessary standardization factors for Δ output were not taken into account. Standardization is generally necessary to convert the output variable Δ output into units of the output variable F _R.

• neue Ausgabegröße = alte Ausgabegröße + (Verzögerungszeit t_V/ Taktzeit T₂) - Δ Ausgang mit Δ Ausgang = neue Ausggangsgröße - alte Ausggangsgröße berechnete Größe als Ausgabegröße F_R ausgegeben (siehe Ablaufplan Seite 9). Der zeitliche Verlauf der Ausgabegröße F_R ergibt sich in entsprechender Weise wie beim ersten Ausführungsbeispiel (Figur 3d) und ist in Figur 3e aufgetragen.

The second method is based on the concept of processing a change in the output signal with a delay time of at least one time cycle T ₂ . During this delay time, which can also include several, for example n cycle times T ₂ , neglecting normalization factors, one becomes, according to the formula:

• new output size = old output size + (delay time t _V / cycle time T ₂ ) - Δ output with Δ output = new output size - old output size calculated size output as output size F _R (see flowchart on page 9). The time course of the output variable F _R results in a manner corresponding to that in the first exemplary embodiment (FIG. 3d) and is plotted in FIG. 3e.

Although the exemplary embodiment has been shown in block diagram form for reasons of clarity, it is also intended to be implemented using a suitably programmed microcomputer. To explain the corresponding program structure, two flow charts are shown below, corresponding to the two methods for determining the correction value. These flow charts speak for themselves, so that no further explanations are necessary in addition to the above.

Exemplary embodiments of the invention have been described using a lambda-controlled mixture metering system for an internal combustion engine. However, the essence of the invention is not restricted in particular to a lambda-controlled mixture metering system. The invention can always be used when the integral behavior of the output signals of a sensor or a probe or in general a signal generating means, in particular for the mixture metering, plays a role and a time delay arises due to the time-clocked, delayed signal processing of these signals. Idle charge control, exhaust gas recirculation control, knock control, extreme value control and the like can be mentioned as further control methods for the mixture composition of an internal combustion engine, in which the invention can be used.

Claims (11)

1.Mixing system for an internal combustion engine with a digital arithmetic unit, in particular a microcomputer, the signal processing sequence of which is tied to clock cycles and with a signal, in particular analog output signals, which are sensitive to operating parameters of the internal combustion engine, in particular an exhaust gas probe sensitive to the air ratio lambda, which is used in a control circuit for Influencing the air-fuel ratio is used and in particular changes its output variable with the air ratio lambda = 1, characterized in that a correction function (24) is provided which influences the influence of a delay time (t _V ) associated with the time-clocked signal processing in the transmission corrected the change in the output of the signal generating means to the mixture formation. 2. Mixture metering system according to claim 1, characterized in that the correction function ('24) determines a correction value as a function of at least the detected delay time (t _v ). 3. Mixture metering system according to claim 1 or 2, characterized in that the correction function (24) determines a correction value as a function of a cycle time (T ₂ ) of the digital computing unit. 4. Mixture metering system according to one of the preceding claims, characterized in that the correction function (24) determines a correction value as a function of the change in the output variable (Δ output) of the signal generating means. 5. Mixture metering system according to at least one of the preceding claims, characterized in that the correction function (24) according to the calculation rule: Correction value = (delay time t _V / cycle time T ₂ ) · Δ output · N with Δ output = nth output variable - (n-1) th output variable and N = normalization factor determines a correction value. 6. Mixture metering system according to at least one of the preceding claims, characterized in that after a change in the output variable for determining an output variable (F _R ), at least one cycle time (T ₂ ) past output variables (F _R ) are processed by the correction function (24) . 7. Mixture metering system according to claim 6, characterized in that the correction function (24) during this period of at least one cycle time (T ₂ ) determines a modified by the correction value-e output variable (F _R ). 8. Mixture metering system according to claim 7, characterized in that the output size (F _R ) for the mixture formation according to the calculation rule: nth output variable = (nm) th output variable + correction value with m = 1, 2, 3, ... is formed. 9. Gemischzumeßsystem according to at least one of claims 1 to 5, characterized in that after a change of the output of the signal generation means for determining an output quantity (F _R) a time by less than one cycle time (T ₂₎ past output size (F _R) of the Correction function (24) is processed. 10. Mixture metering system according to claim 9, characterized in that the output size (F _R ) for the mixture formation according to the calculation rule: nth output variable = nth output variable + correction value is formed. 11. Mixture metering system according to at least one of the preceding claims, characterized in that the output variable (F _R ) is corrected by a correction value only when the output variable of the signal generating means changes.

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