EP1379769A1

EP1379769A1 - SYSTEM AND METHOD FOR CORRECTING THE INJECTION BEHAVIOuR OF AT LEAST ONE INJECTOR

Info

Publication number: EP1379769A1
Application number: EP02729862A
Authority: EP
Inventors: Peter Kuegel; Guenter Veit; Ernst Kloppenburg
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2001-04-10
Filing date: 2002-04-09
Publication date: 2004-01-14
Also published as: US20040158384A1; WO2002084095A1; DE10215610A1; JP2004522045A; DE10215610B4; JP4908728B2; KR20040014488A; US6904354B2

Abstract

The invention relates to a system and method for correcting the injection behavior of at least one injector. Said system comprises a device (22) for storing information (18) and a means (20) for controlling the at least one injector (18) based on the stored information. The invention provides that the items of information are individually determined and obtained by comparing specified values with actual values at a number of test points (P) of at least one injector (18).

Description

System and method for correcting the injection behavior of at least one injector

The invention relates to a system for correcting the injection behavior of at least one injector with a device for storing information about the at least one injector and means for controlling the at least one injector, taking into account the stored information. The invention further relates to a method for correcting the injection behavior of at least one injector, comprising the steps of: storing information about the at least one injector and controlling the at least one injector taking into account the stored information.

State of the art

Electrically driven injectors for fuel injection are used, for example, in the context of common rail systems. With the common rail accumulator injection, pressure generation and injection are decoupled. The injection pressure is generated depending on the engine speed and the injection quantity and is ready for injection in the "rail". The injection timing and quantity are calculated in the electronic engine control unit and implemented by an injector on each engine cylinder via a remote-controlled valve.

Such injectors have different quantity indicators due to their mechanical manufacturing tolerances. A quantity map is to be understood as the relationship between the injection quantity, rail pressure and actuation time. As a result, despite ^' electrically defined control, each individual injector fills the combustion chamber with different amounts of fuel.

In order to achieve the lowest possible fuel consumption in compliance with strict exhaust gas standards and very smooth running, the injectors may only have very small tolerances with regard to the injection quantity during operation. These required small tolerances cannot be met due to the mechanical manufacturing tolerances. In order to ensure a defined injection quantity for the injectors, the injectors are measured for their injection quantity at characteristic operating points after production and classified into classes. The respective class must be known to the engine control unit during operation so that the control can be adapted to the special features of the class in an injector-specific manner. If such a correction of the tolerances by the engine control unit is not possible due to the knowledge of the class, the special injectors must ^{• be} reworked mechanically.

There are numerous ways of storing the class information on the injector, for example by means of various codes, such as by means of bar codes, by means of resistors on the injector or by plain text on the injector. Is the class information through a code on the. Stored injector, the information is transmitted to the control unit by means of a code recognition and subsequent programming. When the class information is stored by means of resistors on the injectors, the information can be read out automatically by the control device. However, additional electrical lines are required. Plain text can be recognized using a camera.

Furthermore, it is possible that electronic storage options are provided in the injectors, in which, for example, the class information is stored. The control unit can read these values from the injector via an interface and use them in subsequent operation. However, this solution has the disadvantage that a separate interface between the control unit and the injectors is required.

The injectors can be classified, for example, in such a way that the injectors are tested at several test points with regard to the injection quantity metering. the. If the measured actual values at all test points lie within a predetermined tolerance window, the injector is rated as good. The actual value of a measuring point is also used to divide the injectors into three tolerance classes. The tolerance windows of the respective classes are 1/3 of the total tolerance at this test point. Since there is only an insufficient correlation between the test points, it is not possible to narrow the tolerance at the other test points. If the injectors are installed on the engine, the class affiliation is programmed into the control unit assigned to the engine. The control unit ^' then corrects the injection quantity for the upper and lower classes according to a pre-assigned map. The middle class is not corrected. Due to the poor correlation between the operating points or the test points, the correction is only possible in the area of the test point used for classification. In the rest of the operational area, a slight adjustment of the quantity metering can only be made on the basis of statistical shifts in mean values between the classes.

Advantages of the invention

The invention offers the advantage that the information is determined by comparing target values with actual values and that the information is individually related to several test points of at least one injector. In the prior art systems that use the class information, the control unit can only make corrections based on this class information. In contrast to this, the control device in the system according to the invention receives precise information about several test points or operating points of each individual injector.

There is the possibility that measures in the control unit individually correct the actuation duration for each injector depending on the target quantity and rail pressure in relation to the nominal map in order to come as close as possible to the target quantity. For this purpose, the control unit receives several, preferably four test values (VL, EM, LL and VE) from the production for each injector. A correction quantity map is constructed from these quantities.

For this purpose, the quantity correction for a number of pressure / control combinations must be determined from the deviations of the injection quantities from their target values from the test values (VL, EM, LL and VE) at the preferably four test points. With the help of these pressure / control combinations, a correlation of the injection quantity to the injection quantity at a test point is determined for each test point. With known values for the quantity deviations (ΔVL, ΔEM., ΔLL and ΔVE), the control unit can thus fill the correction quantity map with numerical values.

Due to the extensive correction possibilities on the basis of the present invention Possibility of allowing larger tolerances on the four production test values and thus increasing the production yield.

The means for controlling the injectors are preferably integrated in an engine control unit. Since the engine control unit is provided for controlling the injectors, it is particularly advantageous if the injector-specific control with the accompanying correction is also carried out by the engine control unit.

The information is preferred. Correction quantities for the quantity map of the at least one injector. A great deal of injector-specific information is conceivable, which of. the control unit can be used for injector-specific control. A particularly reliable control of the injection quantity is obtained, however, when the quantity map of each injector is measured and these measured actual values are compared with target values. Correction ratios can be determined from the comparison, which are then taken into account by the control device in the control.

It can be advantageous for the device for storing information to be a data store attached to the injector. A large number of data can be accommodated in such a data store in a convenient manner. It is also useful that the control device can directly receive the data for further processing by reading out the data memory. It can also be advantageous that the device for storing information is implemented by resistors arranged on the injector. Such coding of the information also offers the possibility of automatically reading the information into the control unit.

Another possibility is that the device for storing the information is implemented by a Barcocle attached to the injector. Such a barcode can be scanned so that the information is also directly available to the control unit with this solution.

It may also be possible for the device for storing information to be implemented by alphanumeric encryption on a label field of the injector. In this embodiment, the programming of the control unit can be done manually. Furthermore, it is conceivable for the alphanumeric encryption to be recorded by a camera, so that the control device can in turn be programmed automatically in this way.

In a preferred embodiment ^'sForm the means for storing information is mounted on the injector semiconductor integrated circuit (IC). Such an IC can be integrated in the head of an injector. The data which are used by the control device are stored in the IC in a non-volatile memory. In this context, it is particularly advantageous that the engine control unit has an integrated semiconductor circuit (IC). With such an integrated semiconductor circuit in the engine control unit, the. Information stored in integrated semiconductor circuits of the injectors is processed, so that ultimately the injector-specific control is made possible.

The system is particularly advantageous in that, by comparing target values with actual values, it is determined whether the injector is within a predefined tolerance range, and the information to be stored is determined for the injectors lying within the predefined tolerance range that the engine control unit calculates an individual correction map for each injector from the stored information and that the injection quantity and / or the injection timing are corrected in accordance with the correction fields. First of all, a comparison of target values with actual values determines whether the injector can be used at all. Once the injector is rated good, the target values and the actual values are used in order to record adjustment values (correction quantities). With the aid of these correction quantities, the control unit then calculates an individual quantity correction map after the values have been programmed into the control unit, so that ultimately a corrected measurement of the accuracy of high accuracy can take place. The method according to the invention builds on the generic method in that the information is determined by comparing target values with actual values and in that the information is individually related to several test points of at least one injector. The method according to the invention thus offers the possibility of an injector-specific control which goes beyond the control based on a classification.

The method can be used particularly advantageously if an engine control unit is used to control the injectors. The method can therefore be carried out using a component which is already present in injection systems.

Correction quantities of the plurality of test points are preferably used as information in the method for determining the quantity correction characteristic diagram. A great deal of injector-specific information is conceivable, which can be used by the control device for injector-specific control.

However, the quantity correction map, i.e. the relationship between the injection quantity, rail pressure and activation time, offers particularly good options for compensating for tolerances using an injector-specific control.

The determination of at least one correction quantity by at least one comparison is advantageous of the target value with the actual value at the several test points of one injector possible.

In a preferred embodiment of the invention it is provided that the correction amount is determined by linear regression of several comparisons of the target values with the actual values at the several test points of an injector.

According to the invention, the correction quantity Δ0 _(n) in the quantity correction map MKK from the _. , Product from the correction value KW _{! N)} and the quantity deviation ΔVEp.b determined from the target value with actual value comparison. (ni / ΔEM _A b. (n) / ΔVL _A b. (n) / ΔLL _Ab . m) of the respective test points according to the formula

AQ _lll} = KW _{n) «AVE _{Ahw {n)} W _{n) = KW _[n) * AEM _{AIW ι)} Q ₍₎ = IOV _(n) * KVL _Ahwm AO _M = KW _η * ALL _Alm

calculated

In a further preferred embodiment of the invention, certain test points are also correlated with one another. By correlating several test points, the effects of measurement errors in the test values can be further reduced.

In a further preferred embodiment of the invention, the amount of correction is achieved by the linear regression of several comparisons of the target values with the actual values determined by at least two correlating test points of an injector on a compensation plane.

In a preferred embodiment of the invention, the correction quantity Δθ _(n ) in the quantity correction characteristic field MKK is also calculated for the case of determining the correction values KW ( _n ) at two correlating test points of an injector at the compensation level according to the following dependency; The correction amount Δθ _(n) is then the sum of the products of the correction value (KW _(ri )) and. the quantity deviation ΔVE _A bw determined from the target value with actual value comparison. (n) or ΔEM _Ab w. ( _n j of the two correlating test points according to the formula

Δö _,,, ,, = _{KW) * AVE _Almm + KW ₍₂₎ * AE, "". t-)

calculated,

The quantity deviations ΔVE _Äb w. u> ^un ΔEM _A b _W. (2) with their correction values KW ₍ u and KW ₍ ) are only an example for calculating the correction quantity Δθ (i, ₂ ). A calculation of the correction quantity ΔQ _(n) is basically possible with any number of quantities - deviations possible.

For the method, the following also advantageously applies that a mean square deviation (RMΞE) is used as a measure of the quality of the regression for comparing the actual values with the target values on the linear regression curve or the linear compensation plane. It is advantageous that in If at least two correlating test points when comparing the target values, the mean square deviation for the same measurement errors at the compensation level is smaller than when comparing the target values with the actual values on the linear regression curve.

In a further embodiment of the invention, there is the possibility that if there is a great deal of test data. of a large number of injectors, the correction quantities are provided by the non-linear combination of several comparisons of the target values. ^" with the actual values of several test points on non-linear regression curves and / or on non-linear compensation planes.

The method is also particularly advantageous in that, by comparing target values with actual values, it is determined whether the injector is within a predetermined tolerance range, and the information to be stored is determined for the injectors lying within the predetermined tolerance range the engine control unit uses the stored information to calculate an individual quantity correction map for each injector and that the injection quantity and / or the injection time are corrected in accordance with the quantity correction codes. drawings

The invention is explained in more detail below with the aid of the associated drawings and exemplary embodiments. Show it:

Figure 1 is a schematic representation of part of a common rail system;

FIG. 2 shows a quantity correction map as a diagram of the dependence of the injection quantity on the rail pressure;

FIG. 3 shows a diagram of the correction quantity at an accumulated rail pressure and a constant injection time as a function of the quantity deviation in a test point;

FIG. 4 shows a diagram of the correction quantity at a constant rail pressure and a constant injection time as a function of the quantity deviation in another test point and

FIG. 5 shows a diagram of the correction quantity in the case of a constant rail pressure / control combination and a constant injection time as a function of the quantity deviation between two correlating test points of an injector. - Description of the embodiments

FIG. 1 shows the high pressure part of the common rail storage injection system. Only the main components and those components which are essential for understanding the present invention are explained in more detail below. The arrangement comprises a high-pressure pump 10, which is connected to the high-pressure accumulator (“rail”) 14 via a high-pressure line 12. The high pressure accumulator 14 is more _. High pressure lines connected to the injectors. In. In the present illustration, a high-pressure line 16 and an injector 18 are shown. The injector 18 is installed in the engine of a motor vehicle. The system shown is controlled by an engine control unit 20. In particular, the injector 18 is controlled by the engine control unit 20.

A device 22 for storing information that relates individually to the injector 18 is provided on the injector 18. The information stored in the device 22, ^• can be taken into account by the engine control unit 20 so that an individual control may be 18 of each injector. The information is preferably correction values for the quantity map of the injector 18. The device 22 for storing the information can be used as a data store, as one or more electrical resistors, as a barcode, by alphanumeric ^encryption or also by a on the injector 18 arranged integrated semiconductor circuit can be realized. The engine control unit 20 can also have an integrated semiconductor circuit for evaluating the information stored in the device 22.

FIG. 2 shows a diagram to explain the invention. The diagram shows a quantity correction map MKK, with a quantity M metered by the injector 18 being plotted against a rail pressure Pκ _a ii. The MKK quantity correction map is based on several injection points (VL, EM, LL, VE). The adjustment values ΔVL, ΔEM ^'ΔLL .DELTA.VE and serve for correction quantity M, which are by comparing Ξoll- values with actual values determined at various rail pressures P ii _Ra at various test points. If necessary, a correction value KW _{(n) is} assigned to the comparison values ΔVL, ΔEM, ΔLL and ΔVE. For example, the injection quantity M at a test point P is assigned the adjustment value ΔEM as a function of a pressure (rail pressure / actuation duration combination) of the injection EM, from which a correction quantity ΔQ _(n) for the control device is determined in the respective test point. The arithmetical correction quantities ΔQ _(n) are based on the adjustment values which result from quantity deviations ΔVL _A bw. _(N>, ΔEMa_ _w. Mi, ΔLL _A bw. Mi ^un d .DELTA.VE _Dev. _(N) are determined in the respective test points, and the associated determined correction values K j _n). In FIG. 2, a correction value KW _{(n) is} assigned to the test point P ΔEM, for example. It can also be seen that numerous test points P can be provided for an injector 18, these resulting over the entire operating range and the quantity correction map MKK. The adjustment values can also be interpolated linearly between the support points defined by test points P, so that ultimately a reliable fuel quantity metering can take place in the entire operating range.

FIGS. 3 to 5 describe how the quantity correction ΔQ _{(n) is determined} for the respective test point.

FIG. 3 is a diagram of the correction quantity Δ0 _(n) at a constant rail pressure ppn and a constant injection time t as a function of the quantity deviation ΔVE _A b. (n) shown. FIG. 3 shows the test point Pl at the rail pressure p _Ra ii 800 bar and the injection time t = 350 μs. Based on the measurement data resulting from the comparison of the target values with the actual values - shown as black dots in FIG. 3 - a linear regression curve 24 results after mathematical linear regression ^. This clarifies the amount of correction Δ0 _(π) in the event of a deviation ΔVE _A b. (N) of the target value at the test point Pl is necessary. The possible correction value KW _(n) that can be used to calculate the correction amount Δ0 ( _n) results from the increase in the linear regression curve 24. For the test point Pl shown in FIG. 3, the increase in the correction value with 1.6 results, for example, from to determine the corrective quantity ΔQ _(n ) is used as a factor for the determined quantity deviation ΔVE _A b _W. ( _n ). The formula to ^'is:

FIG. 4 shows in a diagram the correction quantity ΔQ _(n) in another test point P2 with the same rail pressure Pp.aii -and the same injection time t- as in FIG. 3. The linear regression curve 24 is again shown, which results from the comparison of the target Values with measurement data resulting in the actual values - black dots - result, with KW _(n) as the correction value. a value of, for example, 0.6 results from the increase in the linear regression curve 24. A calculation of the correction amount .DELTA.Q _(nJ takes place in this checkpoint also as the product of KW correction value _(n) and the amount of deviation ΔEM _AEB _(s) in the inspection point P2 after the For ^¬ mel.:

Δ <2 _(-> M = 2 * ΔEΛ / _M _". ₂₎

Figure 5 shows a graph of the correction amount .DELTA.Q _(s) at the same constant rail pressure ^'aii and the same constant injection time t in dependence on the quantity deviation as shown in Figures 3 and 4 but correlated between two test points of an Injek ^¬ tors, such as Pl and P2. Here, the two correlating test points P1 and P2 are shown on a compensation ^plane 26 determined by linear regression. On the basis of the black dots shown, the basic data can be recognized, which is determined by the target / actual Value comparison have arisen and are used for the mathematical determination of a compensation level 26 by means of linear regression. The exemplary values for the rail pressure pR _a _ι = 800 bar and the injection time t 350 = μs, which are already constant in FIGS. 3 and 4, have also been retained in FIG. 5. From Figure 5 there is also a to be calculated correction amount .DELTA.Q _(s) extending out from said sum of the products of the correction value KW _(s) with the amount of deviation .DELTA.VE _Dev. _(N) and ΔEM _Dev. _(N) in this case, in Check points Pl and P2 with

ΔQ,., = KWX * Δ E ₄ , "" + Ä * * AEM. ",,,"

is calculated.

The superimposition of two correlating test points P1 and P2 by means of the compensation level 26 results in corresponding correction values KW ₍₁₎ and K ₍₂ ) from the increase in the compensation level 26, which differ from the correction values of the linear regression curves - as explained in FIGS. 3 and 4 - differentiate.

In comparison to a mean square error RMSE of linear regression curves 24 of Figures 3 or 4 is the respective mathematical mean square error RMSE for a calculation of the correction amount .DELTA.Q _(ι, ₂₎ (Figure 5) niedri ^¬ than that for the calculation of Δθ ₍ i ₎ or ΔQ ( ₂ ). The calculation of the mean square softening RMSE takes place according to the known mathematical methods.

The required correction amount ΔQ (i, ₂ , or its associated correction values KW ₍ D and KW ₍₂ ) are represented more precisely by the two-dimensional compensation plane 26 (FIG. 5) than by a one-dimensional model using linear regression curves 24.

For the amount deviation .DELTA.VE _Dev. _(n) and ΔEM _Ab w. ( _n ) applies that the standard deviation on the linear regression curves 24 (FIGS. 3 and 4) is greater than the standard deviation determined on a compensation plane formed by means of linear regression. 26 (Figure 5). The standard deviations are also calculated using the known mathematical methods.

Correction quantities .DELTA.Q _(n) can thus be calculated from the basic data of different quantities and quality by the control unit from the quantity correction map MKK - FIG. 2. The correction quantities ΔQ _(n) are therefore based on different calculation models.

In a first calculation model, the correction quantities ΔQ. ( _N ) can be calculated on the data of a simple target / actual value comparison. In the respective test point P of the quantity correction map MKK.

In a second model calculating the corrective ^¬ tower narrow Δθ _(n) can be prepared from the base data in the respective test points P1 or P2 are determined according to the method described in FIGS. 3 and 4 and incorporated into the quantity correction map MKK and calculated.

In a third calculation model, the correction amounts .DELTA.Q _(s) of basic data, linked in at least two test points Pl and P2 of an injector 18 may be that described in. Figure 5 Procedures were determined, ^'in the amount correction map MKK incorporated and calculated.

In a fourth calculation model, the correction quantities Δ0 ( _n ) can be calculated from basic data in at least two linked correlating test points P1 and P2 of an injector 18 with a non-linear function and incorporated into the quantity correction characteristic diagram MKK. In this case, however, a great deal of test data from correlating test points P are required in order to be able to use corresponding non-linear dependencies. This possibility is not shown in the figures.

Depending on the quantity and quality of the basic data, the accuracies are lowest according to the first calculation method and highest according to the fourth calculation method.

This opens up the possibility of a more precise injection of the injection quantity M using the calculation models with the greatest accuracy. The preceding description of the exemplary embodiments according to the present invention is only for illustrative purposes and not for the purpose of restricting the invention. Various changes and modifications are possible within the scope of the invention without leaving the scope of the invention and its equivalents.

Claims

claims

1. System for correcting αes tinsprirzverna rens of at least one injector, with a device (22) for storing information (18) of the at least one injector and means (20) for controlling the at least one injector (18) taking into account the stored information, characterized in that the information is determined and related individually by comparing target values with actual values at several test points (P) of at least one injector (18).

2. System according to claim 1, characterized in that the means for controlling the at least one injector are integrated in an engine control unit (20).

3. System according to claim 1 or 2, characterized in that the information is correction quantities (Δ0 _(n) ) for a quantity correction map MKK of the at least one injector (18).

4. System according to any one of the preceding claims, characterized in that the device (22) for storing information is a data memory attached to the injector (18).

5. System according to any one of the preceding claims, characterized in that the means (22) arranged resistors is implemented to store information through an ^'the injector (18).

6. System according to one of the preceding claims, characterized in that the device (22) for storing information is implemented by a bar code attached to the injector (18).

7. System according to any one of the preceding claims, characterized in that the device (22-) for storing information is implemented by alphanumeric encryption on a label of the injector (18). ,

8. System according to any one of the preceding claims, characterized in that the device (22) for storing information is an integrated semiconductor circuit (IC) arranged on the injector (18).

9. System according to any one of the preceding claims, characterized in that the engine control unit

(20) has an integrated semiconductor circuit (IC).

10. System according to any one of the preceding claims, characterized in that

- That by comparing target values with actual values it is determined whether 'the minimum an injector (18) lies within a predetermined tolerance range,

that the information to be stored is determined for the at least one injector (18) lying within the tolerance range,

that the engine control unit (20) calculates the individual quantity correction map (MKK) for the at least one injector (18) from the stored information, and

the injection quantity and / or the injection point are corrected in accordance with the quantity correction characteristics.

11. Method for correcting the injection behavior of at least one injector with the method steps

a) storing the information on the at least one injector (18) and

b) controlling the at least one injector (18) taking into account the stored information,

characterized in that the information is determined and compared by comparing target values with the actual values at individually several test points (P) of at least one injector (18).

12. The method according to claim 11, characterized in that an engine control unit (20) is used to control the injectors (18).

13. The method according to claim 11, characterized in that a correction amount as information

(Δθ ( _n )) of the several test points P can be used for the determination of a quantity correction map (MKK).

14. The method according to claim 13, characterized in that the correction quantities (ΔQ _(n) ) are determined by at least one comparison of the target value with the • actual value at the several test points (P) of an injector (18).

15. The method according to claim 13, characterized in that the correction amount (Δ0 _(n) ) by linear regression of several comparisons of the target values with the actual values at the several test points (P) of an injector (18) on a linear regression curve ( 26) is determined.

16. The method according to claim 13, characterized in that the correction quantities (Δ0 ( _n) ) by the linear regression of several comparisons of the target values with the actual values of at least two correlating test points (P) of an injector (18) a compensation level (26) can be determined.

17. The method according to claim 14 or 15, characterized in that the correction amount ₍ Δθ ₍ n)) in the men- genkorrekturkennfeld (MKK) from the product of a correction value (KW _(n)) and a detected amount of deviation from the desired value with the actual value comparison .DELTA.VE _Abw .- (n) / _A b ΔEM. in / ΔVL _Dev. (n> / ΔLL _Äb w. m) of the test points (P) according to the formula

AQ _υι) = KW _{n) * AVE _{Ahw (n)} Q. ^ KW ^ AM ^ AO _[n) = KW _[n) * AVL _Ahwχn) - ^ KW ^ & LL ^

18. The method according to claim 16, characterized in that the correction quantity (ΔQ _(n) ) in the quantity correction map (MKK) is the sum of the products (P) from the correction values (KW _(n) ) and that from the target value with actual Comparison value determined amount of deviation (.DELTA.VE _Dev. (n)) and (ΔEM _Ab. (n)) of the two kor ^¬ relierenden probes (Pl) and (P2) of an injector (18) according to the formula

ΔO _(1,2) = KW _{1) * AVE _{Ahw (1)} + KW ₍₂₎ * AEM _AlmX

is calculated,

19. The method according to claim 15 and 16, characterized in that a mean square deviation (RMSE) is used as a measure of an approximation of the comparisons of the actual values with the target values on the linear regression curve (24) or the compensation plane (26) becomes.

20. The method according to claim 19, characterized in that when comparing the target values with the actual values of at least two correlating test points (P), the mean square deviation at the compensation plane (26) becomes smaller.

21. The method according to claim 15 and 16, characterized in that by comparing the target values with the actual values at the test points (P) ^' a standard deviation of the correction amount ΔQ _{! N)} on the linear regression curve (24) or Compensation level (26) is determined.

22. The method according to claim 21, characterized in that the standard deviation becomes smaller with the same measurement errors at the compensation plane (26).

23. The method according to claim 13, characterized in that the correction quantities (ΔQ _(n) ) by non-linear links of several comparisons of the target values with the actual values of several test points (P) of the at least one injector (18) on non-linear ones Regression curves and / or non-linear compensation levels can be determined.

24. The method according to claim 11 to 23, characterized in that

by comparing target values with actual values, it is determined whether the at least one

Injector (18) lies within a predetermined tolerance range, that the information to be stored is determined for the at least one injector (18) lying within the tolerance range,

that the engine control unit (20) calculates the individual quantity correction map (MKK) for the at least one injector (18) from the stored information and

the injection quantity and / or the injection point are corrected in accordance with the correction values (KW) of the quantity correction indicators (MKK).