DE10026273C2 - Method for cylinder equalization in an internal combustion engine - Google Patents

Description

The invention relates to a method according to the preamble of claim 1.

In the case of a multi-cylinder internal combustion engine, the injection of fuel into the combustion chambers by scattering the properties of the injectors a systematic mistake. Due to manufacturing tolerances and different wear during the life are identical with the same injection time and otherwise identical Boundary conditions different amounts of fuel fed to individual cylinders. The different Amounts of fuel lead to a different Power output of each cylinder, what next to one Increasing uneven running also increases the amount of harmful exhaust gas components.

DE 197 00 711 C2 describes a method for compensating the sy systematic error on an injectors Internal combustion engine known. The known method fits Compensation of the systematic error the injection time and / or the injection start angle in a corresponding manner on.

DE 198 27 105 A1 describes a method for operating a Internal combustion engine known in which as a control parameter for Control the injection the fuel pressure is used systematic errors caused, for example, by deposits on injection valves arise.

In the article "A common rail concept with pressure modulated Injection ", valet Th., Bürgler L., MTZ Motortechnische Zeitschrift 61, No. 4, 2000, pp. 230 to 238,  describes an injection system that modulates pressure is working. This is between the common rail and the injector a pressure modulator is provided which measures the fuel pressure adapts accordingly. The pressure modulator is as Piezo actuator designed.

From US 3,575,145 A an injection system is known in which the fuel flow to individual cylinders is measured and Means are provided to control the injection pressure of each Adjust cylinders differently. That way an even supply of fuel to the cylinders reached.

The object of the invention is another Procedure for correcting the injection behavior of a Provide injector.

The object of the invention is characterized by the features of Claim 1 solved.

Further advantageous embodiments of the invention are in the dependent claims specified.

The invention is explained in more detail below with reference to the figures explained. Show it:

Fig. 1, different injection pressure curves,

Fig. 2 shows the injection quantities of two injectors and

Fig. 3 shows a schematic structure of an injection device.

Fig. 1 shows a diagram which is divided into three partial diagrams. The three partial diagrams are arranged one above the other, with the crankshaft angle KW being plotted on the abscissa. The first partial diagram shows a first corrected injection pressure 1 , a standard injection pressure 2 and a second corrected injection pressure 3 . The standard injection pressure 2 corresponds to the injection pressure that is set by the control unit for injection based on predetermined control programs. Deviations from the manufacturing tolerances and a corresponding aging of the injection device can, however, result in too little fuel being injected for combustion if the control parameters specified by the control unit are observed. In this case, the fuel pressure is corrected in accordance with the first corrected injection pressure 1 and the injection pressure is increased compared to the standard injection pressure. Due to the higher injection pressure, a larger amount of fuel is injected into the cylinder of an internal combustion engine in the same injection time. In this way, an insufficient injection quantity of the injection device is compensated for.

Likewise, the deviation from the manufacturing tolerances and a corresponding aging of the injection device can lead to the injection device injecting too much fuel into the cylinder of an internal combustion engine due to the predetermined control parameters. In this case, the control unit compensates for the malfunction of the injection device in such a way that the fuel pressure is reduced below the standard pressure 2 to a second corrected injection pressure 3 . As a result of the lower pressure, with otherwise the same boundary conditions, less fuel is injected into the cylinder of the internal combustion engine during an injection process than at a standard injection pressure 2 .

A first quantity curve 4 , a second quantity curve 5 and a third quantity curve 6 are plotted in the middle partial diagram over the crankshaft angle KW. The first volume flow rises steeply after the start of injection at crankshaft angle A and reaches a maximum value at crankshaft angle B. In the further course, the first quantity course 4 drops to a third crankshaft angle C, in order then to drop steeply again to a fourth crankshaft angle E to the value zero. The quantity curve 4 represents the flow rate per second through the injection device. The first quantity curve 4 corresponds to an injection with the first increased injection pressure 1 .

The second quantity curve 5 has a curve analogous to the first quantity curve 4 , but the maximum value at the second crank angle B and also the value at the third crank angle C are smaller than in the first quantity curve 4 . This is because the second quantity curve 5 represents the fuel quantity per second at the standard injection pressure 2 . Since the standard injection pressure 2 is lower than the increased injection pressure 1 , the flow rate is also correspondingly lower.

The third quantity curve 6 has a curve analogous to the second quantity curve 5 , but the maximum value for the second crankshaft angle B and for the third crankshaft angle C is smaller than for the second quantity curve 5 . The flow rate is the lowest in the third flow curve 6 , since the injection pressure corresponding to the second corrected injection pressure 3 is also the lowest.

In the third part of the diagram, the needle stroke is Injector shown. At the first Crankshaft angle A the needle starts from the sealing seat to take off to a at the second crankshaft angle B. End position with the injection cross section fully open to reach. At the third crankshaft angle C the Injector closed again so that the Injection needle moves towards the sealing seat and at the fourth crankshaft angle E again at the sealing seat sits and the injection is finished.

From Fig. 1 it can be clearly seen that the increase or decrease in the corrected injection pressure 1 , 3 already starts a predetermined angular distance D earlier in order to increase the maximum or minimum injection pressure at the start of injection, ie at the first crankshaft angle A to reach. The corrected injection pressure is constant over the entire injection period.

Preferably the values for the increased or decreased injection pressure as factors in the form of a Map stored. In addition, preferably to Injection pressure the fuel temperature at a precise Dimensioning of the injection quantity considered. The Correction parameters are stored as adaptive maps.

The characteristic maps are preferably stored as pre-control values, so that even in transient operation only a very small one Deviation of the cylinders with each other at the Torque output occurs.

Another advantage of the adaptive maps is that correcting different amounts of fuel at the same time  can be. For example, the front and Post-injection compared to the main injection different corrections. To do this for the pre and post injection different values for the increased or the reduced injection pressure filed as for the main injection.

Fig. 2 shows the amount of injection of two injectors with a constant injection pressure. It can be seen that the injection quantity of the first injector 8 varies significantly compared to the second standard injector 9 and injects more fuel than the second injector with short injection times. With longer injection times, the first injector injects less fuel than the second injector. The adjustment of the injection pressure is therefore preferably stored as a function of the injection time. For example, in order to compensate for the first injector according to FIG. 2, a reduced injection pressure must be used for an injection time that is shorter than a first injection time T1. With an injection time that is greater than the first injection time T1, an increased injection pressure must be used for the first injector in order to ensure that the first and the second injector inject the same amount of fuel at a predetermined injection time.

The values for the corrected injection pressure become after known methods, such as in DE 197 00 711 C2 described during the operation of the internal combustion engine determined and corrected adaptively. This way too compensated for an aging of the injector.

Fig. 3 shows schematically the structure of an injection device having an injection needle 20 which is axially movably arranged in an injection chamber 23. The tip of the injection needle is assigned to a sealing seat 21 , so that the injection chamber 23 is separated from injection holes 22 in the closed position . The injection chamber 23 is connected to a fuel accumulator via a channel 24 . An actuator 25 is provided, which is connected to the injection needle 20 via an actuator 26 . The actuator 25 is connected via a control line 27 to a control unit 28 which is connected to a data memory 30 . Programs for controlling the actuator 25 and thus for controlling the position of the injection needle 20 are stored in the data memory 30 . When the actuator 25 is actuated, the injection needle 20 is lifted off the sealing seat 21 and fuel is injected via the injection holes 22 into a cylinder 29 of an internal combustion engine.

Claims (4)

1. A method for cylinder equalization with respect to the fuel injection quantity for an internal combustion engine having a plurality of cylinders, in which a control parameter for controlling the injection is corrected in order to compensate for a systematic error in an injection device, the fuel pressure being used as the control parameter, characterized in that values for a increased or decreased fuel pressure are stored in a map depending on the injection time. 2. The method according to claim 1, characterized in that a pressure change before the start of injection continuously to an increased or decreased value is changed so that at the start of the injection increased or decreased fuel pressure. 3. The method according to any one of claims 1 or 2, characterized characterized in that the increased or decreased Fuel pressure increases continuously after the end of injection the regular fuel pressure is reduced or increased. 4. The method according to any one of claims 1 to 3, characterized characterized that values for an increased or reduced fuel pressure in an adaptive map in Dependence on an accelerator pedal position and the speed of the Internal combustion engine are stored.