EP1697624A1 - Method and device for controlling an internal combustion engine - Google Patents

Abstract

The invention relates to a method and device for controlling an internal combustion engine comprising an inlet pipe leading to a cylinder input where a gas input valve is placed. Said engine also comprises a drive for the gas input valve which makes it possible to adjust a gas input valve lift for at least two values. The engine also comprises an injection valve for metering fuel and a spark plug which controls the crankshaft angle of air-fuel mixture ignition. Said internal combustion engine is controlled in a following manner: a fuel is metered at least once during the intake stroke of a cylinder when the valve lift (VL) passes from one value to the other and at least one final injection is carried out in a dosing manner only when the valve lift (VL) is really carried out.

Description

description

Method and device for controlling an internal combustion engine

The invention relates to a method and a device for controlling an internal combustion engine.

High demands are being placed on internal combustion engines with regard to their performance and efficiency. At the same time, emissions have to be low due to strict legal regulations. Such requirements can be met well if the internal combustion engine is equipped with gas exchange valves and corresponding drives for these, in which the valve lift course differs depending on the operating point of the internal combustion engine. This can reduce throttle losses when the air is drawn in and, if necessary, quickly set high exhaust gas recirculation rates.

It is known to adjust the valve lift of a gas inlet valve of the internal combustion engine between a small and a high valve lift. For example, the Porsche 911 Turbo is equipped with a device for adjusting the valve lift of the gas inlet valve and the gas outlet valve. Furthermore, the internal combustion engine of this vehicle is provided with a camshaft on which a cam with a short stroke and two further cams with a higher stroke are formed for each gas inlet valve. The cam lift is transmitted to the gas inlet valve by means of a transmission unit. The transmitter unit is designed as a cup tappet, which comprises a cylinder element and an annular cylinder element arranged concentrically to this. The cam with a small stroke acts on the cylinder element, while the cams with the higher stroke act on the ring cylinder element. Depending on the switch position of the bucket tappet, either the Transfer small or higher stroke to the gas inlet valve. When the internal combustion engine is idling, the small cam lift is transmitted to the gas inlet valve. This results in reduced friction losses due to the small diameter of the cam and the cylinder element used in this operating state and the lower valve lift.

Furthermore, a higher charge movement is achieved. As a result, the emissions of the internal combustion engine can be reduced and at the same time the fuel consumption can be kept low. The low valve lift is maintained at low and medium loads. Throttle losses can also be reduced by a corresponding phase adjustment between the gas inlet valve and the gas outlet valve and a resulting internal exhaust gas recirculation rate. In the event of high load requirements on the internal combustion engine, a switch is made to the higher valve lift. For a high level of driving comfort of a vehicle in which such an internal combustion engine is arranged and for low pollutant emissions, it is important that the switchover from the small valve lift to the higher valve lift takes place without misfiring.

The object of the invention is to provide a method and a device for controlling an internal combustion engine which ensures that low pollutant emissions are generated.

The object is achieved by the features of the independent claims. Advantageous embodiments of the invention are characterized in the subclaims.

The invention is characterized by a method and a corresponding device for controlling an internal combustion engine with an intake manifold, which is led to an inlet of a cylinder on which a gas inlet valve is arranged, a valve drive for the gas exchange valve, by means of which the valve lift of the gas inlet valve in at least two levels is adjustable, an injection valve that admits fuel, and a spark plug, by means of which the crankshaft angle of the ignition of the air / fuel mixture is controlled. If the valve lift is to be switched from one stage to another stage, fuel is metered in at least once in the intake stroke of the cylinder and at least the last metering of fuel depends on whether the valve lift has actually been switched from one stage to the other , In this way it can easily be ensured that there are no misfires or burns with a very high fuel excess, i.e. a significantly higher proportion of fuel than the stoichiometric air / fuel ratio, even if an actual switchover from one stage to the other stage of the valve lift is very difficult to predict.

In an advantageous embodiment of the method for controlling the internal combustion engine, fuel is metered in once during the intake stroke of the cylinder and the fuel mass is determined depending on whether the valve lift has actually been switched from one stage to the other. This has the advantage that it is particularly simple.

In a further advantageous embodiment of the method for controlling the internal combustion engine, fuel is metered in at least once during the intake stroke of the cylinder without taking into account whether the valve lift has actually been switched from one stage to the other. This ensures a very good mixture preparation of the air / fuel mixture, which is a prerequisite for a good combustion process and thus low raw emissions of pollutants from the internal combustion engine. In a further advantageous embodiment of the method, at least the last metering of fuel takes place only when the valve lift has actually been switched from one stage to the other. This means that, on the one hand, a very good mixture preparation can be guaranteed if the stage with a lower valve lift has actually been set and thus low pollutant emissions are ensured, and on the other hand, a desired air / fuel ratio can also be set if the stage is actually with higher valve lift is set.

In a further advantageous embodiment of the method, the fuel mass, which is metered without taking into account whether the valve lift has actually been switched from one stage to the other, is determined such that a desired air / fuel ratio results when the valve lift actually occurs with the stage with lower valve lift. This allows the mixture to be processed very well and an air / fuel ratio to be set precisely if the stage with a lower stroke is actually set.

In a further advantageous embodiment of the method, the fuel mass, which is metered without taking into account whether the valve lift has actually been switched from one stage to the other, is determined in such a way that there is an increased fuel fraction than the desired air / fuel ratio, if the valve lift actually takes place with the stage with a lower valve lift. This has the advantage of an improved mixture preparation if the stage with a higher valve lift is actually set. In a further advantageous embodiment of the method, if the valve lift is to be switched from one stage to the other stage, fuel is metered into the intake stroke of the cylinder at least once, and at least the last metering of fuel depends only on whether a switchover takes place the valve lift from one stage to the other has actually taken place when the speed is greater than a predetermined threshold value, which is preferably approximately 200 ° revolutions per minute. This has the advantage that, on the one hand, the computational effort for determining the fuel mass to be metered is reduced below this threshold value and, on the other hand, surprisingly, the probability of failure to switch the stage is significantly greater at speeds greater than the predetermined threshold value than at speeds below the predetermined value Threshold and thus the risk of misfiring is low.

In a further advantageous embodiment of the method, the ignition angle is adapted as a function of a variable which characterizes the metering of fuel and which depends on whether the valve lift has actually been switched from one stage to the other. This has the advantage that a possibly worse mixture preparation can be taken into account when setting the ignition angle, in such a way that lower pollutant emissions are guaranteed.

A further advantageous embodiment of the method is the size, the force mass and / or the crankshaft angle of the metering of the fuel, which depend on whether the valve lift was switched from one stage to the other. has actually occurred. This has the advantage that these sizes are characteristic of the mixture preparation.

Embodiments of the invention are explained below with reference to the schematic drawings. Show it:

FIG. 1 shows an internal combustion engine with a control device,

FIG. 2 shows a further view of parts of the internal combustion engine according to FIG. 1,

3 shows a flowchart of a first embodiment of a program for controlling the internal combustion engine when the valve lift is to be switched over from a small valve lift to a high valve lift,

4 shows a sequence diagram of the program according to FIG. 3 for controlling the internal combustion engine when the valve lift is to be switched over from a high valve lift to a small valve lift and

Figures 5 and 6 another embodiment of a program for controlling the internal combustion engine.

Elements of the same construction and function are identified with the same reference symbols in all figures.

An internal combustion engine (FIG. 1) comprises an intake tract 1, an engine block 2, a cylinder head 3 and an exhaust tract 4. The intake tract preferably comprises a throttle valve 11, further a collector 12 and an intake manifold 13, which leads to a cylinder ZI via an intake port in the engine block is guided. The engine block further comprises a crankshaft 21 which is coupled to a piston 24 of the cylinder ZI via a connecting rod 25. The cylinder head comprises a valve train with an inlet valve 30, an outlet valve 31 and valve drives 32, 33. The gas inlet valve 30 and the gas outlet valve 31 are driven by means of a camshaft 36 (see FIG. 2) _r on which cams 39, 39a and 39b are formed acting on the gas inlet valve 30. Furthermore, cams, not shown, are provided — possibly on a further camshaft, which act on the gas outlet valve 31.

A total of three cams 39, 39a, 39b (FIG. 2) are assigned to the gas inlet valve 30. The cams 39, 39a, 39b act on the gas exchange valve 30 via a transmission unit 38. The transmission unit 38 is designed as a tappet. It comprises a cylinder element 38a and an annular cylinder element 38b arranged concentrically to this. The cam 39 acts on the cylinder element 38a. The cams 39a, 39b act on the ring cylinder element 38b. In a switch position of the bucket tappet, only the stroke of the cam 39, which is less than the cams 39a and b, is transmitted to the gas inlet valve 30. In a further switching position of the cup tappet, the strokes of the cams 39a and b are transmitted to the gas inlet valve 30. The switching position of the cup tappet can be achieved by a corresponding control of an actuator provided in the cup tappet and is preferably carried out hydraulically.

The valve drive 31, 32 can, however, also be designed as an alternative. For example, the camshaft be designed and cooperate with an actuator such that, depending on the desired valve lift, different cams act on the gas exchange valve or.

The cylinder head 3 (FIG. 1) further comprises an injection valve 34 and a spark plug 35. Alternatively, the injection valve can also be arranged in the intake manifold 13. The exhaust tract 4 comprises a catalytic converter 40. An exhaust gas recirculation line can be led from the exhaust tract 4 to the intake tract 1, in particular to the collector 12.

Furthermore, a control device 6 is provided, to which sensors are assigned, which detect different measured variables and each determine the measured value of the measured variable. The control device 6 determines, depending on at least one of the measured variables, manipulated variables which are then converted into one or more actuating signals for controlling the actuators by means of corresponding actuators.

The sensors are a pedal position sensor 71, which detects the position of an accelerator pedal 7, an air mass meter 14, which detects an air mass flow upstream of the throttle valve 11, a temperature sensor 15, which detects the intake air temperature, a pressure sensor 16, which detects the intake manifold pressure, a crankshaft angle sensor 22, which detects a crankshaft angle to which a speed N is then assigned, a further temperature sensor 23 which detects a coolant temperature, a camshaft angle sensor 36 which detects the camshaft angle and an oxygen probe 41 which detects a residual oxygen content of the exhaust gas and, if appropriate, a sensor which detects whether the gas inlet valve 30 is operated with a low or high valve lift. Depending on the embodiment of the invention, any subset of the sensors mentioned or additional sensors can be present.

The actuators are, for example, the throttle valve 11, the gas inlet and gas outlet valves 30, 31, the injection valve 34, the spark plug 35, the adjusting device 37 or the transmission unit 38.

In addition to the cylinder ZI, the internal combustion engine preferably also has further cylinders Z2, Z3, Z4, to which corresponding sensors and actuators are assigned and which accordingly to be controlled. The control device 6 corresponds to a device for controlling the internal combustion engine.

A program for controlling the internal combustion engine is preferably started when the internal combustion engine is started. The start takes place in a step S1 (FIG. 3), in which variables are initialized if necessary.

In step S2 it is checked whether the current rotational speed N is greater than a predetermined threshold value N_THR of the rotational speed, which is preferably approximately 2000 revolutions per minute. If the condition of step S2 is not met, a third fuel mass MFF3 is determined in a step S6, taking into account the expected air mass in the cylinder for this working cycle, based on the desired stage of the valve lift VL, and taking into account the air to be set / Fuel ratio. Furthermore, the metering of the third fuel mass MFF3 is controlled in step S6.

If, on the other hand, the condition of step S2 is met, a step S4 checks whether a switchover of the valve lift VL from a small valve lift LO to a high valve lift HI has been requested since the last operating cycle of the cylinder ZI.

If this is not the case, the processing is continued in step S6. Subsequent to step S6, the processing is continued in step S8, in which an ignition angle IGN is determined as a function of the engine speed N, a desired torque TQ_REQ and, if appropriate, further variables. For example, instead of the desired torque TQ REQ, another one can load the internal combustion engine. size representative of the machine. Furthermore, the ignition angle IGN can also be determined depending on further variables with a view to the desired minimization of pollutant emissions, such as NOX emissions.

The program then remains in a step S10 for a predetermined waiting period T_W or also for a predetermined crankshaft angle before the processing is continued again in step S2.

If, on the other hand, the condition of step S4 is fulfilled, a first fuel mass MFFl is determined in a step S12, the first fuel mass MFFl is e.g. determined in such a way that a desired air / fuel ratio is established in the cylinder ZI, provided that the valve lift VL of the gas inlet valve 30 is the small valve lift LO in the current intake stroke. Furthermore, the actual metering of the first fuel mass MFFl is then controlled in step S12. Alternatively, in step S12, the first fuel mass MFFl can also be selected such that there is a higher proportion of fuel in the cylinder ZI than the desired air / fuel ratio, provided that the valve lift VL of the gas inlet valve 30 is the low valve lift LO is.

The program then remains in step S14 for the predetermined waiting period T_W, which can differ from that of step S10. The waiting period T_W in step S14 is preferably dimensioned such that it can be determined in a subsequent processing of step S16 whether the valve lift VL in the current intake stroke is actually the low valve lift LO or actually the high valve lift. tilhub is HI. However, it is so short that step S16 can be processed as early as possible.

The actual valve lift VL is preferably detected either by means of the suitable sensor or, in a simple embodiment, it is possible to switch from a small valve lift LO to a high valve lift HI on the basis of the course of the intake manifold pressure or else on the basis of the course of a hydraulic pressure, in which case the switching takes place hydraulically _r or also be detected on the basis of electrical signals when the switchover is performed electrically. For example, the actual course of the intake manifold pressure while the gas inlet valve 30 is in its open position can be used to determine whether the low valve lift LO or the high valve lift HI is in fact by comparison with corresponding values for the small valve lift LO and / or the high valve lift HI is set.

If it is recognized in step S16 that the actual valve lift VL is the small valve lift LO, the processing is continued in step S8.

On the other hand, if it is recognized in step S16 that the actual valve lift VL is the high valve lift HI, a second fuel mass MFF2 is determined in step S18. The second fuel mass MFF2 is determined such that the sum of the first and second fuel masses MFFl, MFF2 corresponds to the desired air / fuel ratio in the cylinder ZI at the high valve lift HI. Furthermore, the metering of the second fuel mass MFF2 is controlled in step S18. A correction value IGN_COR for the ignition angle IGN is then determined in a step S20, depending on the second fuel mass and / or the crankshaft angle CRK_MFF2 of the metering of the second fuel mass MFF2. By means of this correction value, the quality of the mixture preparation, which may have deteriorated, can be determined on the basis of the late addition of the second fuel mass MFF2, and it can thus be ensured by influencing the ignition angle IGN that the pollutant emissions are minimized.

In a step S22, the ignition angle IGN is then determined as a function of the correction value IGN_COR, the rotational speed, the desired torque TQ_REQ and, if appropriate, further or alternative variables which the person skilled in the art uses for this purpose. Furthermore, the ignition of the air / fuel mixture in the cylinder ZI is also controlled in step S22. The processing is then continued in step S10. The waiting time period T_W in step S10 is preferably dimensioned such that after step S10 the processing is then continued in step S2 when a new working cycle of the cylinder ZI has started.

If, in step S12, the first fuel mass MFFl is determined in such a way that the desired air / fuel ratio is set for the small valve lift, it is ensured that the pollutant emissions in the event of a switchover of the valve lift from the small valve lift LO that has not actually occurred high valve lift HI are minimized. If, on the other hand, an increased first fuel quantity MFF1 is determined in step S12, this has happened in the event that there is actually no switchover from the lower valve lift LO to the higher valve lift HI. has increased pollutant emissions, but this has the advantage that in the event of a possibly more likely actual switchover from the low valve lift LO to the high valve lift HI, a better mixture preparation is ensured due to the earlier metering of a larger first fuel mass MFFl.

Tests have shown that the reason for a deviation between the desired and the actually set valve stroke VL e.g. in a hydraulic system may be due to a foaming of the hydraulic fluid during the operation of the internal combustion engine. Gas bubbles located in this foamed fluid lead to a change in the compressibility of the fluid, which in turn can result in a desired switchover not taking place in good time. It has surprisingly been found that this foaming occurs particularly strongly above the threshold value N_THR.

The embodiment of the program for controlling the internal combustion engine according to FIG. 4 differs from that according to FIG. 3 in that it is checked in a step S4 'whether a switchover of the valve lift VL from the high valve lift HI to the low valve lift LO has been requested. It is further checked in a step S16 'whether the actual valve lift VL has been switched from a high valve lift HI to a low valve lift LO. The programs according to FIGS. 3 and 4 are preferably processed parallel to one another.

FIGS. 5 and 6 show an alternative embodiment of the program according to FIG. 3, wherein only the steps that differ from those according to FIG. 3 are also described. Step S4 takes place in the event that a Change of the valve lift VL from the low valve lift LO to the high valve lift HI was requested, a step S26 in which the program remains for the waiting period T_W. The waiting period T_W is selected in step S26 such that a subsequent step S28 is processed if it can be determined whether the valve lift VL has actually been switched from the low valve lift LO to the high valve lift. On the other hand, the waiting period T_W of step S26 is selected such that step S28 is processed as early as possible.

It is then checked in step S28 whether the actual valve lift VL has changed from the small valve lift LO to the high valve lift HI.

If this is the case, the sum of the first and second fuel masses MFFl, MFF2 is determined in step S30 and metering of the sum of the first and second fuel masses MFFl, MFF2 is controlled. In this case, both the first and the second fuel masses MFFl, MFF2 are only metered at a point in time when it is already certain whether the actual valve lift VL has changed from the small valve lift LO to the high valve lift HI. In this case, the fuel mass required for the desired air / fuel ratio in the cylinder ZI can always be reliably measured.

In a step S32, the correction value IGN_C0R is then determined as a function of the sum of the first and second fuel masses MFFl, MFF2 and / or the crankshaft angle CRK_MFF1_2 of the metering of the fuel mass into the cylinder ZI. In a subsequent step S34, the ignition angle IGN is then dependent on the correction value IGN COR, the speed N, the Desired torque TQ_REQ and possibly other sizes or alternatively determined from other sizes.

On the other hand, if the condition of step S28 is not fulfilled, i.e. If the actual valve lift VL has not changed from the small valve lift LO to the high valve lift HI, the first fuel mass MFFl is determined in a step S38.

The correction value IGN_COR of the ignition angle IGN is then determined in a step S40 as a function of the first fuel mass MFFl and / or the crankshaft angle CRK_MFF1 of the metering of the first fuel mass MFFl into the cylinder ZI.

In a subsequent step S42, the ignition angle IGN is then determined as a function of the correction value IGN_COR, the rotational speed N, the desired torque TQ_REQ and further variables or alternative variables, and the ignition is then controlled at the predetermined ignition angle IGN.

In all embodiments, the metering of the first, second and third fuel masses MFFl, MFF2, MFF3 can in turn be divided into more than one actual injection. Corresponding programs are also processed for the other cylinders Z2-Z4.

Claims

claims

1. Method for controlling an internal combustion engine with - an intake manifold (13), which is led to an inlet of a cylinder (ZI to Z4) on which a gas inlet valve (30) is arranged, - a valve drive (32) for the gas inlet valve ( 30), by means of which the valve lift (VL) of the gas inlet valve (30) can be set in at least two stages, - an injection valve (34), which measures fuel, and - a spark plug (35), by means of which the crankshaft angle of the ignition of the air / Fuel mixture is controlled - in which, if the valve lift (VL) is to be switched from one stage to another stage, fuel is metered in at least once in the intake stroke of the cylinder (ZI to Z4) and at least the last metering of fuel depends on whether the valve lift (VL) has actually been switched from one stage to the other.

2. The method of claim 1, wherein fuel is metered at least once during the intake stroke of the cylinder without taking into account whether the switching of the valve lift (VL) from one stage to the other has actually occurred.

3. The method according to any one of the preceding claims, in which at least the last metering of fuel takes place only when the switching of the valve lift (VL) from one stage to the other has actually occurred.

4. The method according to any one of the preceding claims, in which the fuel mass, which is metered without taking into account whether the switching of the valve lift (VL) from one stage to the other has actually taken place, is determined in such a way that a desired air / fuel ratio results when the valve lift (VL ) with the stage with lower valve lift (VL).

5. The method according to any one of claims 1 to 3, wherein the fuel mass, which is metered without taking into account whether the switching of the valve lift (VL) from one stage to the other has actually occurred, is determined so that an increased Kraftsto fanteil than the desired air / fuel ratio when the valve lift (VL) is actually at the lower valve lift (VL) stage.

6. The method of claim 1, in which fuel is metered once during the intake stroke of the cylinder (ZI to Z4) and the fuel mass is determined depending on whether the switching of the valve lift (VL) from one stage to the other has actually occurred ,

7. The method according to any one of the preceding claims, wherein if the valve lift (VL) is to be switched from one stage to the other stage, fuel is metered in at least once during the intake stroke of the cylinder (ZI to Z4) and at least the last metering of fuel only depends on whether the valve lift (VL) has actually been switched from one stage to the other if the engine speed (N) is greater than a threshold value (N THR).

8th . The method of claim 7, wherein the threshold (N_THR) is approximately 2000 revolutions per minute.

9. The method according to any one of the preceding claims, wherein the ignition angle (IGN) is adjusted depending on a size that characterizes the metering of the fuel and which depends on whether a switching of the valve lift (VL) from one stage to the other actually is done.

10. The method according to claim 9, characterized in that the size is the fuel mass and / or the crankshaft angle of the metering of the fuel, which depend on whether the valve lift (VL) has actually been switched from one stage to the other.

11. Device for controlling an internal combustion engine with - a suction pipe (13), which is led to an inlet of a cylinder (ZI to Z4), on which a gas inlet valve (30) is arranged, - a valve drive (32) of the gas inlet valve (30 ), by means of which the valve lift (VL) of the gas inlet valve (30) can be set in at least two stages, - an injection valve (34), which measures fuel, and - a spark plug (35), by means of which the crankshaft angle of the ignition of the air / fuel Mixture is controlled, the device having means which control that fuel is metered in at least once in the intake stroke of the cylinder when the valve lift (VL) is switched from one stage to another stage. should follow, and control at least the last metering of fuel depending on whether the valve lift (VL) has actually been switched from one stage to the other.