DE4122139C2 - Method for cylinder equalization with regard to the fuel injection quantities in an internal combustion engine - Google Patents

Description

The invention relates to a method for cylinders equality in terms of fuel injection quantities in an internal combustion engine.

Rotation occurs when the internal combustion engine is running uniformities based on the fact that individual cylinders of the engine under different amounts of fuel are injected. Among other things, tolerances of the individual injection components that only play a role can be reduced at a particularly high cost. The emerging rotational irregularities can Example in motor vehicles causes vibrations chen.

DE 33 36 028 A1 is a Quiet regulations known to the Dampens the vibrations that are on under  different fuel injection quantities are based. For example, it is known to have speed deviations single cylinder from the average speed of the Capture internal combustion engine. It did emphasized that the function of such Smooth running control only for a limited speed range can be optimized so that a compensation of Vibrations only in a limited rotation number range is possible.

The object of the invention is therefore that the different fuel Speed irregularities based on injection quantities as far as possible in the whole Avoid engine operating area. This object is achieved by the method according to the features of claim 1.

The method according to the invention Claim 1 has over the teaching of DE 33 36 028 by the structure of a PT1 circuit has the advantage that it avoids the of different fuel inputs rotational irregularities based on injection quantities an internal combustion engine practically over the ge entire engine operating range.

The basis of the procedure is the registration of the Speed acceleration of each combustion advance gangs. The measured values obtained are compared with each other compared and found deviations. Because of Such deviations become the fuel on injection volumes of the individual cylinders changed so that eventually deviations are avoided and so rotation non-uniform based on this phenomenon The internal combustion engine can be eliminated.

An embodiment of the method is preferred, in which sliding across all cylinders of the medium value of the measured acceleration values telt (cf. claims 3 and 4). In this way, instatio  a comparison of the engine operating conditions Fuel injection quantities are brought about.

In a further preferred embodiment of the The procedure is measured in the event of a deviation speed acceleration value from the mean of the Acceleration of the associated cylinder one of the next injection processes che injection quantity supplied. It is preferred the correction already in the next injection process carried out (see claim 5).

In a further preferred embodiment of the The procedure is the mean of the sum of the individual additional injection quantities formed and deducted from all additional injection quantities (see claim 7). Even with sudden changes in the middle rotation acceleration is ver through this compensation avoided that the mean of the compensating amounts of becomes zero and thus a deviation from the average injection quantity the specified target value of the injection quantities occurs. A "drift" the compensation amounts are avoided in this way the.

Further advantages result from the remaining Un claims (see claims 2, 6 and 8).

The invention is based on the drawing tion explained in more detail. Show it:  

Fig. 1 is a highly schematic functional diagram of an internal combustion engine tion with a Steue,

Fig. 2 shows the qualitative course of speed and angular acceleration in an internal combustion engine with four cylinders and

Fig. 3 is a flowchart for determining the rotational acceleration values and for performing cylinder equalization in an internal combustion engine.

Fig. 1 shows a highly schematic functional sketch of an internal combustion engine, with a control tion again. The internal combustion engine 1 has, for example, four cylinders 3 in the present case. The fuel injection into the cylinders is regulated via suitable control lines 5 , which are connected to a control unit 7 . This evaluates signals from a sensor 9 , the signals of which are passed on to the control unit 7 via a feed line 11 . The sensor 9 scans a segment wheel 13 , which rotates synchronously with the crankshaft of the internal combustion engine 1 .

In operation of the internal combustion engine 1 , there are four segments during the scanning of the rotating segment wheel 13 for the 4-cylinder internal combustion engine, it being possible to assume that the segment S1 is limited by the times T1 and T2 and the segment S2 by the times T2 and T3, etc.

The following is intended to be general again on the emergence of rotational irregularities To be received.

Due to deviations in the amounts of fuel injected into the cylinders 3 of the internal combustion engine 1 shown in FIG. 1, different cylinder pressure values arise during combustion. This means that the accelerating torques based on combustion also differ. The relationship between engine torque M and speed n is given by the following equation:

In this equation, M _B denotes the accelerating torque, M _L the load torque and θ _ges the mass moment of inertia in relation to the crankshaft.

Neglecting the effects of efficiency and the influence of the crankshaft angle, the accelerating torque M _{B is} proportional to the injected fuel mass, so that the following equation results:

M _B = c. Q _E

In this equation, Q _E denotes the average amount of fuel delivered per work cycle and c a constant. At stationary engine operating points, the accelerating torque M _B corresponds to the load torque M _L , so that the following equation results for the average fuel quantity delivered per work cycle:

If the delivered fuel quantity of a cylinder m deviates from the mean fuel quantity by the amount ΔQ _{E, m} , the following equations result for the individual delivery quantities, where z denotes the number of cylinders of the internal combustion engine:

The following formulas for the effective accelerating torques M _{B of} the individual cylinders result from the equations mentioned:

From equations (2.2) and (2.4a / 2.4b), the relationship between rotational accelerations for each cylinder - averaged over one work cycle - and the injection quantities for stationary engine operating points result from:

The following equation results for a cylinder m:

For an internal combustion engine with, for example, four cylinders, these equations result in the qualitative profile of rotational speed n and rotational acceleration shown in FIG. 2, the outlined values in each case being averaged over one cylinder.

At constant mean speed, ie in the "stationary" case, the mean rotational acceleration is calculated from the following equations over z work cycles:

In the "unsteady" case, that is to say in the event that the mean value of the accelerating torque M _{B is} less than or greater than the load moment M _L , the mean value of the individual accelerations per work cycle results from the following equations:

By converting this equation, the following formula results:

The formula can be further simplified as follows:

Finally the following equation results:

From the two systems of equations (2.6) and (2.7) it can be seen that, with the aid of the method according to the invention, the detection of the injection quantities fluctuating from cylinder to cylinder, that is to say the systematic scatter of the injection quantities, is also possible for unsteady operating points. For this purpose, the "mean rotational acceleration", that is, the rotational acceleration averaged over z work cycles according to equation (2.6) is to be subtracted from the "instantaneous value" of the rotational acceleration, that is to say from the rotational acceleration averaged over one work cycle. If one assumes that fluctuations in the rotation of the internal combustion engine are only based on the fact that different injection quantities are supplied to the individual cylinders, the deviations in the injection quantities can be approximately calculated from the following equation:

In this equation, n is determined by the following formula:

With the help of the relationships set out here, the method of cylinder equalization will now be discussed in more detail with reference to FIG. 3.

First, the speed of the internal combustion engine characterized by the fact that for each work cycle the Internal combustion engine at least one electrical Im pulse is generated. For example, an Im pulse wheel are used, the output signal in a speed sensor is evaluated.

It is assumed for the following considerations went that the internal combustion engine after the four clock process works and that the firing intervals are constant. It is also assumed that for each work cycle generates exactly one speed pulse its position with respect to top dead center O. T. a cylinder is unchanged.

The generation and detection of the speed pulse for the cylinder (i + 1) is indicated in step 1 of the flow diagram according to FIG. 3.

In step 2 of the flow chart according to FIG. 3, the throughput time Δt _i between two rotational speed pulses, which are assigned to the cylinders (i + 1) and (i), is determined.

Starting from the time Δt _i that elapses between two successive pulses, the instantaneous speed n _i results from the following equation:

From this equation, the following formula can be used to calculate the mean rotational acceleration n _i between two work cycles from the following equation:

If, for example, the derivative of the speed is calculated, i.e. the rotational acceleration in segment S2, then the difference between speed n ₁ in segment S1 and speed n ₂ in segment S2 is determined by the width Δt ₂ of segment S2 according to equation (3.1b) divided. This type of calculation is necessary because the speed can only be measured over a segment and not at a specific point in time.

In step 3 of the flowchart in FIG. 3, the calculations according to equations (3.1a) and (3.1b) are indicated. Finally, in the third step, the mean value of the rotational acceleration is determined, as shown in equation (2.8b).

For eliminating rotational irregularities due to different fuel injection levels It should be noted that the different Amounts of fuel can be based on the fact that constant funding duration different funding rates available or at constant funding rates below there are different funding periods. Can too a combination of these conditions is available.

For further considerations, the simplification chung, assumed that a constant we degree of efficiency is given and that the influence of the cure belwinkels is negligible. Among these before suspensions can be assumed that the Drehbe acceleration directly proportional to the injected Amount of fuel.

This results in the following relationship for the injected fuel quantities: If the rotational acceleration caused by a cylinder deviates from the mean rotational acceleration, an additional injection quantity ΔQ _{e, i} , which is proportional to this deviation, is supplied to this cylinder during the next injection to compensate. The additional injection quantity is calculated using the following equation:

In this equation, ΔQ _{e, i} denotes the amount of fuel additionally to be supplied to cylinder i, the mean rotational acceleration over two crankshaft revolutions, _i the rotational acceleration caused by cylinder i, and c _opt a constant. The individual additional amounts of fuel to be supplied are continuously added while the method described here is being carried out, the resulting sum being denoted by ΔQ _{zu, i} and resulting from the following equation:

If one compares equation (4.1) with equation (2.8a), it follows that the constant c _{Opt has} to be chosen depending on the moment of inertia of the motor.

The comparison of equations (4.1) and (4.2) with equation (2.5c) shows that the calculation of the balancing sets has a PT1 behavior. From equations (4.1), (2.5c) and (2.2) it can be deduced that in the ideal case for C _Opt :

This design would be a rotational nonuniformity with the first calculation of the associated off compensate for the same amount. All is required However, the validity of the linearization of the together between the injection quantity and the delivered quantity Torque.

In any case, must apply

This condition marks the stability limit. If this is exceeded, this has compensation amounts result, which is the same with the next metering or greater rotational nonuniformities call sign.

The determination of the additional injection quantity ΔQ _{E, i which} serves to equalize the cylinders is shown in step 4 of the flow diagram according to FIG. 3, where the first line shows the equation (4.1). The summation of the equalization amounts results from the second sub-step of the fourth process step of the flow diagram according to FIG. 2. Finally, averaging is carried out in a third sub-step.

All summed up compensation quantities ΔQ _{zu, i} are compensated with respect to this mean value (compare step 5 of the flow chart in FIG. 3):

By adhering to this "coupling condition" a "Drifting" of the equalization quantities avoided, and it it ensures that the actual mean Injection quantity over all cylinders equal to the gefor second setpoint.

Alternatively to those introduced by the equations (4,3) and (4,3-b) coupling condition it is also possible, the corresponding equation (4,3b) compensation amounts _to .DELTA.Q with each determination of an .DELTA.Q _{E, i} according to equation (4.1) as follows to calculate:

The additional injection quantity for a special cylinder i determined according to the steps specified here is added to the mean injection quantity which is specified by a setpoint Q _{E, setpoint} , this setpoint being determined, for example, via the accelerator pedal. The individual setpoint of the injection quantity Q _{set, i of} the cylinder i can thus be calculated from the following equation:

Q _{target, i} = Q _{E, target} + ΔQ closed _{, i} (4.5)

In addition to these two methods mentioned, there is also the possibility of maintaining the compensation with respect to the mean value of the compensation amounts in the following way: First, one of the cylinders of the internal combustion engine is determined and designated k. Then its compensation amount is calculated according to the following equation:

The ΔQ is calculated for all cylinders i ≠ K _{, i} according to equations (4.1) and (4.2).

From the above, in particular from the func ons diagram according to FIG. 3, it can be seen that the calculation of the additional injection quantity should preferably be completed before the next fuel metering takes place. The reason for this is that in any case, when considering the coupling condition according to equation (4.4), a flow is taken to a compensation amount that must be taken into account with the immediately following fuel metering for a cylinder.

This results from the fact that after the occurrence of a speed pulse for cylinder i, the following procedural steps must take place: First, the calculation according to equations (4.2) and (4.3) or (4.4) of the value ΔQ _{zu, i} must be carried out. The fuel can then be metered for the cylinder (i + 1). The fuel delivery is then activated. Then the combustion in the cylinder (i + 1) can begin.

If the time required for fuel metering is not taken into account, the compensation quantities ΔQ actually conveyed can have a mean value that differs from zero _, despite the coupling condition according to FIG. (4.4).

If so, the procedure also indicates compliance the coupling condition in which a single cylinder k is used for this, the sum of the compensation making quantities zero, the disadvantage of that Coupling condition only every two crankshafts rotations is observed. This will increase the settling times of one carried out in this way  Procedure slightly different from the other two Procedure for compliance with the coupling condition.

It should also be noted that in the case of the method for compensating for the mean value of all equalization quantities, which was mentioned in second place, with integer arithmetic, the calculation of the value ΔQ _{E, i} / (z - 1) may result in rounding errors due to which ultimately the mean value becomes non-zero.

Based on these considerations, the method shown in FIG. 3 should preferably be used in step 5: after each recalculation of a compensation quantity ΔQ _{zu, i} , the mean value of all compensation quantities of all cylinders can be calculated and subtracted from all compensation quantities.

Considering the numerous successive process steps that have to be carried out for the cylinder i after the occurrence of the speed pulse, it may be necessary, especially when taking into account the inertia of actuators controlled by this method, that the distance between the speed pulse and top dead center is too great . In this case, it can happen that the compensation of the injected fuel quantity for a cylinder can no longer follow in the immediately following metering. This is indicated in step 6 of the Flußdia gram according to FIG. 3, that the metering may possibly not already be carried out with the cylinder (i + 1) but only with the cylinder (i + 2).

Through the method described here for adaptive Cylinder equation can be an expense position and to balance an injection system we be reduced considerably. This is described bene procedures over the entire engine operating area rich, also in unsteady engine operation are applicable.

Finally, it is also possible with the summing up tion or integration of the individual values extreme values to be recorded separately in order to To record errors of the overall system. It shows So it turns out that this process ultimately also for Diagnosis of an internal combustion engine used that can.

Claims (8)

1. A method for cylinder equalization with respect to the fuel injection quantities of an internal combustion engine, characterized in that the rotational acceleration for each combustion process associated with the respective cylinder is detected for adaptive equation of the cylinders, that the individual measured values are compared with one another and that in the event of deviations in the measured values from one another the fuel injection quantities are changed accordingly until the deviations are balanced. 2. The method according to claim 1, characterized in net that to determine the rotational acceleration Difference between the speed in two at a time the following segments is divided by the Lead time of the latter of the two segments. 3. The method according to claim 1 or 2, characterized characterized in that the mean of the measured Spin values are determined.   4. The method according to claim 3, characterized shows that the mean sliding over all Zy linder is determined. 5. The method according to claim 3 or 4, characterized ge indicates that in the event of a deviation in the case of egg Torque generated during a combustion process the average of the spin acceleration proper cylinder at one of the next injections tongues, preferably at the next injection, an additional injection quantity (positive or nega tiv) is supplied. 6. The method according to claim 5, characterized records that the additional injection quantity of the Deviation between rotational acceleration and mean approximate proportio nal is. 7. The method according to claim 5 or 6, characterized ge indicates that the fed to a cylinder additional injection quantity is added up, and that this total value when determining the zylin the assigned setpoint is taken into account. 8. Method according to one of the preceding An sayings, characterized in that to avoid of overdeterminations in the metering additional Amounts of fuel are ensured that the Sum of additionally the individual cylinders total fuel injected is zero.