EP0140065A1 - Electronic apparatus for controlling the fuel amount in an internal combusion engine - Google Patents

Abstract

The invention is directed to an apparatus for influencing control quantities of an internal combustion engine by means of which vibrations of the entire vehicle in the lower engine speed range, particularly at idling, are to be eliminated. This is accomplished by allocating to each cylinder a regulating unit which regulates the control quantities influencing the respective cylinder, such as fuel metering, exhaust gas recirculation, start of injection, duration of injection, air/fuel ratio, ignition time point, et cetera, for the smoothest possible running condition.

Description

State of the art

In motor vehicles, a low-frequency oscillation of the entire vehicle frequently occurs in the lower speed range, especially when idling. This oscillation is often referred to as "shaking" and is in the range between 1 and 5 Hz.

This shaking is due to the series production of the injection equipment. This causes tolerances on the injection components, which cause different injection quantities from cylinder to cylinder. These differences in fuel quantity lead to rapid changes in torque, which excite the oscillating structure of the engine and body. Shaking is therefore an inevitable consequence of manufacturing tolerances.

These low-frequency vibrations can be damped e.g. in that the fuel quantities to be injected into the individual cylinders are corrected. Such a device for damping the shaking comprises e.g. a controller that changes a predetermined fuel setpoint depending on the rapid torque changes so that these torque changes are as small as possible.

Advantages of the invention

The device according to the invention for influencing control variables of an internal combustion engine with the features of the main claim has the task of carrying out the correction of the fuel quantities to be injected into the individual cylinders quickly, precisely, safely and with the aim that each cylinder delivers the same torque, and thereby the engine runs smoothly. This is achieved in that a smooth running control is set up in which each cylinder is assigned its own control.

Advantageous further developments and improvements of the device specified in the main claim are possible through the measures listed in the subclaims.

drawing

Embodiments of the invention are shown in the drawing and explained in more detail in the following description. FIG. 1 shows the basic structure of a smooth running control for an internal combustion engine, FIG. 2 shows the timing diagram of this smooth running control and FIGS. 3 to 5 show possibilities for integrating the smooth running control into an existing fuel metering device.

Description of the embodiments

Figure 1 shows the structure of a smooth running control for an internal combustion engine. This smooth running control 10 comprises z controls 11, 12 and 13, where z is the number of cylinders of the internal combustion engine. Furthermore, the smooth running control 10 includes storage devices 14, 15 and 16, two synchronization devices 17 and 18, and a device for forming an average value 19. For a better understanding of the smooth running control 10, FIG. 1 also shows an idling control 20, one of the position of the accelerator pedal dependent controller 21, a fuel metering device 22 and the internal combustion engine 23 are shown.

The z controls 11, 12 and 13 are now connected on the one hand to the respectively associated z storage devices 14, 15 and 16 and on the other hand to the output of the device for forming an average value 19. This device 19 is acted upon by the output signals of all z memory devices 14 to 16. The inputs of the z storage devices 14 to 16 are connected to the synchronization device 17, while the outputs of the z controls 11 to 13 are connected to the synchronization device 18. These two synchronization devices 17 and 18 are now controlled by a signal dependent on the internal combustion engine 23. The internal combustion engine 23 itself is connected to the fuel metering device 22, which in turn is connected to the synchronization device 18, the idle control 20 and the accelerator pedal-dependent control 21.

The mode of operation of the smooth running control shown in FIG. 1 can best be described with the aid of the time diagram shown in FIG. In FIG. 2, this is a time diagram of an internal combustion engine with four cylinders. The period of two crankshaft revolutions is shown, i.e. 720 ° KW. During this period, combustion took place in each of the four cylinders.

In this time diagram, I and J denote two actual signals that are generated using a segment wheel. This segment wheel, which is connected to the crankshaft, has four segments which are distributed symmetrically on its circumference. Each pulse of the actual signal J now corresponds to a segment of this segment wheel. The length of each pulse of this actual signal J corresponds to the time it takes for a segment of this segment wheel to pass through an imaginary plane perpendicular to the segment wheel. Since four segments of the segment wheel pass through the imaginary plane during a crankshaft revolution, but since only two burns take place in the cylinders during this time, exactly two segments of the segment wheel pass through the imaginary plane perpendicular to the segment wheel between two burnings. The time between two burns is thus divided into two time segments with the help of these two segments of the segment wheel. Due to the symmetry of the segment wheel, and since the crankshaft angular velocity is always slightly higher immediately after combustion than immediately before combustion, these two time periods, e.g. J21 and J22, are always of different lengths. The shorter of the two periods, e.g. J21, indicates This means that combustion is always taking place, while the longer of the two periods, e.g. J22, announces an upcoming combustion.

After a one-time adjustment of the segment wheel on the crankshaft, the simulated combustion times V of the individual cylinders, which are also called synchronization signals, can be precisely determined with the aid of the actual signal J. These combustion times V of the individual cylinders and their relationship with the actual signal J are shown in the time diagram in FIG.

This determination of the combustion times V from the actual signal J is carried out in both synchronization devices 17 and 18 of FIG. 1. The synchronization device 17 switches the actual values I1, I2 or Iz to the corresponding storage devices 14, 15 or 16 with the aid of the simulated combustion times V, these actual values I1, I2 to Iz also being formed by the synchronization device 17 with the aid of the actual signal J. The actual values I1, I2 to Iz are the time periods between two combustion times, as shown in FIG. 2. The synchronization device 18 likewise determines the simulated combustion times V with the aid of the actual signal J, and thus switches the control values S1, S2 and Sz formed by the control devices 11, 12 and 13 as control signal S to the fuel metering device 22.

The control signal S is shown in the time diagram of FIG. 2. It consists of the control values S1, S2 to Sz of the individual cylinders, these control values being formed by the respectively associated control devices. For example, the control value 11 is produced by the control device 11 from the actual value I1 buffered by the storage device 14 and an average value Mz. The mean value Mz is from the Device 19 is formed from all temporarily stored actual values I1, I2 to Iz.

If the internal combustion engine is e.g. precisely at the time T, as shown in the time diagram in FIG. 2, there is firstly a combustion in the cylinder 2 at this moment, secondly, the synchronization device 17 transfers the actual value I1, i.e. the time period from the combustion of the cylinder 1 to the combustion of the Cylinder 2 to the storage device 14, and thirdly, the synchronization device 18 connects the control value S3 for the subsequent combustion of the cylinder 3 to the fuel metering device 22. This control value S3 is activated shortly after the time T so that the associated control device can also set this new control value. This means that this new manipulated variable is dependent on all previous actual values.

The entire smooth running control 10 thus generates an actuating signal S for actuating the fuel metering device 22 from an actual signal I, which is obtained with the aid of a segment wheel. influenced by an idle control 20 and / or by an accelerator pedal-dependent control 21. The fuel metering device 22 then determines, for example, from these input signals. the amount of fuel to be injected into the internal combustion engine 23.

- Since the controls 11 to 13 can also have integral behavior, for example, and since the idle control 20 can also have integral behavior, it is possible that these two I control components work against each other. To prevent this from happening, it must be quiet regulation 10 can be integrated into the entire injection system of the internal combustion engine. This is possible, for example, in that the smooth running control 10 can only influence the entire injection system dynamically. For this dynamic influencing, the sum of the manipulated values S1 to Sz must be 0, ie the average amount of fuel that is supplied to the internal combustion engine less or more due to the smooth running control must be 0 via z injections. This requirement for integrating the smooth running control 10 into the entire injection system can be met, for example, with the aid of one of the changes in the smooth running control shown in FIGS. 3 to 5.

Figure 3 shows the block diagram of part of the smooth running control, in this example the integration of the smooth running control in the entire injection system is realized in that the mean value of the control signal S is subtracted from the output signals of the integrating components of the controls assigned to the individual cylinders. In this example, the control 11 consists of an integrating component 30, a proportional component 31, two subtraction points 32 and 33 and an addition point 34. The input signals I1 and Mz fed to the control 11 are first linked to one another at the subtraction point 32. The output signal of this subtraction point 32 is supplied to the integrating component 30 and the proportional component 31. The output signal of the proportional component 31 is connected to the addition point 34, which is further subjected to the output signal of the subtraction point 33. This output signal of the subtraction point 33 is formed on the one hand from the output signal of the integrating portion 30 and from the mean value of the control signal S. The output signal of the addition point 34 now represents the control value S1, which is fed to the synchronization device 18. The output signal of this synchronization device 18 is the control signal S, which is fed to a device for forming an average 35, the output signal of which then represents the average of the control signal S. This device for forming an average 35 can consist, for example, of a low-pass filter.

As is indicated in FIG. 3, the control signal S is not only fed back to the control 11, but also to the controls 12 to 13 assigned to the other cylinders. This feedback of the control signal S to all the controls 11 to 13 of the smooth running control 10 is achieved that the mean value of the control signal over z burns is 0.

In FIG. 4, the smooth running control is integrated into the entire injection system by subtracting the mean value of the integrating components of the controls assigned to the individual cylinders from the output signals of these integrating components of the individual controls. The control 11 then consists of an integrating component 40, a proportional component 41, two subtraction points 42 and 43 and an addition point 44. The input signals I1 and Mz fed to the control 11 are connected to one another at the subtraction point 42. The output signal of this subtraction point 42 is supplied to the integrating component 40 and the proportional component 41. The output signal of the integrating portion 40 is now connected to a summation point 45 sen, which is further subjected to the output signals of the integrating components of the controls associated with the other cylinders. The output signal of this summation point 45 is fed to a device for forming an average value 46, the output signal of which is connected to the node 47. This connection point 47 is linked to all the controls assigned to the individual cylinders. In the control system 11 shown in FIG. 4, the connection point 47 is connected to the subtraction point 43, which is further subjected to the output signal of the integrating component 40. The addition point 44 is connected on the one hand to the output signal of this subtraction point 43 and on the other hand to the output signal of the proportional component 41. The output signal of the addition point 44 represents the manipulated variable S1. By forming an average of all the output signals of the integrating components of the controls assigned to the individual cylinders and by subtracting this average value from these output signals of the integrating components of the individual controls, it is now achieved that the requirement after integrating the smooth running control into the entire injection system.

FIG. 5 shows a further possibility of integrating the smooth running control into the entire injection system, in which the mean value of the manipulated values of the controls assigned to the individual cylinders is subtracted from the output signal of the integrating components of these controls. The control 11 consists, for example, of an integrating component 50, a proportional component 51, two subtraction points 52 and 53 and an addition point 54 Input signals I1 and Mz supplied are linked to one another at the subtraction point 52. The output signal of this subtraction point 52 is now fed to the integrating component 50 and the proportional component 51. The output signal of the integrating part is connected to the subtraction point 52, the output signal of the proportional part to the addition point 54. This addition point 54 is also subjected to the output signal of the subtraction point 53, the output signal of this addition point 54 represents the manipulated variable S1. This manipulated variable S1 is led to an addition point 57, to which the manipulated values of the controls assigned to the other cylinders are also connected are. The output signal of this addition point 57 is fed to a device for forming an average value 56, the output signal of which is connected to a node 55. All of the controls assigned to the individual cylinders are connected to this connection point 55, as is shown, for example, in the control 11 with the connection of the connection point 55 to the subtraction point 53. This feedback of the mean value of the control values of the controls assigned to the individual cylinders to the output signals of the integrating components of these controls ensures that the smooth running control only has a dynamic effect, that is to say that the control signal S is zero over z-combustions.

The smooth running control described is only intended to prevent the vehicle from vibrating in the lower speed range, especially when idling. This is achieved in that the smooth running control is only effective in a certain speed range. The transition areas from this area of the active smoothness control to speeds at which the smoothness control is not effective, can be covered, for example, with a control of the smooth running control. In addition, it is also possible to evaluate the output signal of the smoothness control in the transition areas with a factor that is between 0 and 1, which prevents the output variable of the smoothness control from increasing or falling suddenly. In the operating case of the controlled smooth running control, the output variable of the smooth running control is further multiplied by a fuel quantity-dependent factor which is between 0 and 1 in order to achieve a soft increase in the manipulated variable in the event of a sharp drop in speed.

In the case of the smooth running control described, the actual signal, that is to say the time period between two combustion times, was determined with the aid of the segment wheel. It is also possible to generate a speed signal using a fast tachometer generator or by means of a gearwheel with a subsequent pulse generator and frequency voltage converter. An actual signal for the smooth running control can be generated by integrating this speed signal from injection to injection or from synchronizing pulse to synchronizing pulse. A further possibility for generating the actual signal would be a peak value evaluation of the speed signal between two injection quantities.

The combustion times required for the provision of the actual signal are determined in the smooth running control described by dividing the time period between two combustion times into two time segments. Since the switching of the actual signal to the storage devices and / or the If the control values are switched through to the fuel metering device under certain circumstances not exactly at the time of combustion, it is possible to extend the smooth running control described with the aid of a counter so that this counter is based on a reference signal, e.g. a needle stroke pulse, a start of injection pulse, a start of combustion pulse, etc. ., is reset, and controls the two synchronization devices at certain, predeterminable counter readings. This makes it possible to generate the switching through of the two synchronization devices at arbitrary, but fixed times. The counter can now either count up depending on the speed and then deliver the synchronization pulses to the two synchronization devices at certain counter readings, or it counts up with a fixed frequency and determines the synchronization times depending on the speed. It is also possible that the counter is reset with every synchronization pulse and with every reference pulse.

In the described smooth-running control the four _'segments of Semgentrads were distributed uniformly over the circumference of the wheel. With the help of these segments, the time between two combustion times was divided into a short and a long period. To reinforce the difference between these short and long periods of time, it is now possible to design the segments of the segment wheel asymmetrically. In the case of the described smooth running control in an internal combustion engine with four cylinders, this would mean that only two opposing segments have the same length. This asymmetry has no influence on the determination of the actual signal I, since the actual signal I represents the time period between two combustions and this time period comprises two segments.

Under normal operating conditions, the segment wheel divides the time between two combustion times into a short and a long period. Interference signals with a lower frequency than the injection frequency can now be superimposed on these time periods. This means that short and long periods of time are no longer evenly changed. The synchronization devices now determine whether a time period is longer than the previous and the subsequent one, they carry out a maximum time check. A synchronization counter, which is increased by 1 at the end of each time period, is always checked when the maximum time check e.g. has noticed a long period of time. If the synchronization is correct, the ends of the long periods of time always fall on e.g. odd number of synchronization counts. If the malfunction causes the end of a long period of time to fall on an even-numbered synchronization counter, the synchronization is incorrect. If an incorrect synchronization is detected, it is checked whether in the next e.g. An incorrect synchronization occurs again after 20 periods. The synchronization is only changed if this is the case.

It is also possible to detect malfunctions by always subtracting the last two periods. Depending on the result of this subtraction, a value is written into a shift register. By comparing the values of the shift register with specified values, malfunctions can be identified and then corrected accordingly. The size of the shift register and also the specified values that characterize the malfunction must be determined experimentally.

In the described smooth running control, the control signal S was fed to the fuel metering device 22, which then e.g. affects the amount of fuel to be injected into the internal combustion engine. It is of course also possible for the actuating signal S to directly or indirectly influence other control variables of the internal combustion engine, e.g. the exhaust gas recirculation, the injection timing, the injection duration, the fuel / air ratio, the ignition timing, etc.

The device shown and described in Figures 1 to 5 can e.g. can be realized with the help of an analog circuit structure. It is particularly advantageous to use the smooth running control described and, if appropriate, also further control and / or regulating devices for fuel metering, e.g. using a suitably programmed microprocessor. With such a computer solution, however, it is then possible that the block diagrams shown can no longer be recognized, since they have been replaced by subroutine structures, time-division multiplexing, etc.

The smooth running control described can be used in internal combustion engines of various functional principles, that is to say in self-igniting internal combustion engines, in spark-ignited internal combustion engines, etc. It is particularly advantageous that, depending on the functional principle of the internal combustion engine, the control system assigned to each cylinder of the internal combustion engine indirectly or directly influences several control variables of the internal combustion engine.

Claims (18)

1. A device for influencing control variables of an internal combustion engine, characterized in that a control is assigned to each cylinder of the internal combustion engine, and that each control forms an actuating value for the cylinder assigned to it from an actual value assigned to it and an all common value. 2. Device according to claim 1, characterized in that the last assigned to each control actual value is buffered. 3. Device according to claim 2, characterized in that the common mean value is generated from the temporarily stored actual values. 4. Device according to claim 3, characterized in that a .Stellsignal is produced by synchronization from an actual signal of the actual value assigned to each control and from the control values formed by the controls. 5. Device according to claim 4, characterized in that the synchronizations depend directly or indirectly on the times of the burns in the individual cylinders of the internal combustion engine. 6. Device according to claim 5, characterized in that the synchronization is generated with the aid of reference signals, counters and comparators. 7. Device according to claim 6, characterized in that the reference signals are needle stroke pulses, injection start pulses, combustion start pulses, etc., which occur with every or every second engine revolution. 8. The device according to claim 5, characterized in that the synchronizations are monitored, and that the subsequent synchronizations are changed after two incorrect synchronization within a predetermined, specific time. 9. Device according to claim 4, characterized in that the actual signal is a signal directly or indirectly dependent on the smooth running of the internal combustion engine, and the actuating signal is a signal directly or indirectly influencing the combustion of the internal combustion engine. 10. The device according to claim 9, characterized in that the smooth running of the internal combustion engine is detected with the help of the times of the _' burns in the individual cylinders of the internal combustion engine, and the combustion of the internal combustion engine, for example with the aid of fuel metering, exhaust gas recirculation, the time of injection, the injection duration, the fuel / air ratio, the ignition timing, etc. is influenced. 11. The device according to claim 10, characterized in that the time period between two combustion times of the individual cylinders of the internal combustion engine is used as a measure of the smooth running of the internal combustion engine. 12. The device according to at least one of claims 1 to 11, characterized in that the influencing of control variables on average over the number of cylinders corresponding combustion is equal to 0. 13. The device according to at least one of claims 1 to 12, characterized in that the device is effective only in a certain, predetermined speed range and is controlled in the adjacent transition areas so that a sudden increase or decrease in the control signal does not occur. 14. Device for detecting the instantaneous speed of the crankshaft, in particular in connection with at least one of claims 1 to 13, for deriving a signal characterizing the smooth running of the internal combustion engine with a symmetrical segment wheel connected to the crankshaft and with a time measuring device for measuring the throughput time of a segment of the Segment wheel by an imaginary plane perpendicular to the segment wheel, characterized in that the time period between two combustion times is divided into two time periods by means of the segment wheel, whereby that of the two time periods immediately following a combustion time is shorter than the other time period, and in that thereby the time of a combustion is recognized. 15. The device according to claim 14, characterized in that with the help of an alternating arrangement of long and short segments on the segment wheel, the time of combustion is detected even more reliably. 16. The device according to claim 14 or 15, characterized in that a diagnosis of the workability of the individual cylinders of the internal combustion engine is carried out with the aid of the different lengths of the two time periods between two combustion times. 17. The device according to claim 16, characterized in that the smallest time period between two combustion times is used as a measure of the smooth running of the internal combustion engine. 18. Device according to claim 14 or 15, characterized in that each time period is compared with the previous and the subsequent time period, that a synchronization counter is incremented with each comparison, that the synchronization counter is checked depending on the result of the comparison, and that depending on the if necessary, the synchronization is changed within a predeterminable, certain time carried out checks of the synchronization counter.

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