DE10020627A1 - Method for operating a fuel supply system for an internal combustion engine, in particular a motor vehicle - Google Patents

Abstract

The invention relates to a fuel supply system (1) for an internal combustion engine, especially of an automobile. In said fuel supply system (1), fuel can be pumped into a pressure accumulator (2) by a pump (6, 10). The pressure in said pressure accumulator (2) can be measured and can be controlled in such a way that an anticipated pressure (prbk) should result in the pressure accumulator (2). The pressure control valve (4) can be regulated to a predetermined value by means of a control device (16). Said control device (16) enables an anticipated pressure to be determined in the pressure accumulator (2) and enables the operativeness of the pressure control valve (4) to be determined based on the anticipated pressure and the measured pressure.

Description

State of the art

The invention relates to a method for operating a Fuel supply system for an internal combustion engine in particular a motor vehicle in which fuel from a pump is pumped into a pressure accumulator in which the pressure in the pressure accumulator is measured, and at which the pressure in the pressure accumulator by actuating one Pressure control valve is changeable. Furthermore concerns the invention a corresponding Fuel supply system for an internal combustion engine as well as a control device for such Fuel supply system.

For example, an internal combustion engine Motor vehicle are increasingly demanding in With a view to reducing fuel consumption and of the exhaust gases generated at a simultaneously desired increased performance. To this end, modern ones Internal combustion engines with a fuel supply system provided, in which the supply of fuel in the Combustion chamber of the internal combustion engine electronically, in particular with a computer-aided control unit, controlled and / or is regulated. It is possible to put the fuel in one  Air intake pipe of the internal combustion engine or directly into the Inject the combustion chamber of the internal combustion engine.

Especially with the latter type, the so-called Direct injection, it is required that the fuel is injected into the combustion chamber under pressure. To this Purpose is a pressure accumulator in which the Fuel pumped by a pump and under one high pressure is put. From there the fuel is then via injectors into the combustion chambers of the Internal combustion engine injected.

Among other things, due to the high pressure, it is possible that Components of the fuel supply system such. B. change due to aging. So it is possible that Pressure control valve with which the pressure in the pressure accumulator can be controlled and / or regulated, slowly its Functionality changed. It is also possible that the pressure control valve due to contamination suddenly fails. Such changes in function of the pressure control valve can dropouts or one other faulty operation of the internal combustion engine Have consequence.

Object and advantages of the invention

The object of the invention is a method for operating of a fuel supply system for one To create an internal combustion engine with which an error of Pressure control valve is recognized quickly and safely.

This task is carried out in a procedure or a Fuel supply system of the type mentioned at the beginning solved according to the invention in that the pressure control valve is controlled such that an expected pressure in should result in the pressure accumulator, and that from the expected  Pressure and from the measured pressure on the Functionality of the pressure control valve is closed.

Between the control of the pressure control valve and the resulting pressure in the pressure accumulator a defined context. This connection can be determined in advance for an intact pressure control valve. This means that there is an expected pressure for each control known, which is in an intact pressure control valve would have to adjust. This expected pressure and the actually measured pressures become according to the invention used on the functionality of the Close pressure control valve.

With the invention it is thus possible to have a defect in the Recognize pressure control valve. The invention Diagnostic methods of the pressure control valve can be done without greater effort can be carried out quickly and safely. The diagnostic procedure also has no negative influences on the running behavior of the internal combustion engine or on its Emissions.

In a first embodiment of the invention, the expected pressure and the measured pressure with each other compared, and the pressure control valve is considered defective recognized when the measured pressure is significantly different from that expected value deviates. So in this first case compared absolute pressures. It is easy and can be carried out quickly and requires little effort.

In a second embodiment of the invention, a expected pressure gradient from the expected pressure determined, it is a measured pressure gradient from the measured pressure, it will be the expected Pressure gradient with the measured pressure gradient compared, and the pressure control valve is considered defective  recognized when the measured pressure gradient is significantly different from deviates from the expected pressure gradient. In this second Case are not compared, but absolute pressures only their pressure gradients. So mistakes of the Diagnostic method based on offsets, for example due to leakage avoided.

In this case, it is particularly advantageous if that Pressure control valve opened in a linear manner or is closed so that the expected pressure gradient is about is constant.

In a third embodiment of the invention, the expected pressure depending on the size of the company Internal combustion engine, particularly depending on the Engine speed determined. So that will achieved that in the diagnostic procedure Dependency of the pressure in the pressure accumulator z. B. from the Engine speed is taken into account. Each the higher the speed of the internal combustion engine, the higher is also the delivery of fuel and therefore the pressure in the pressure accumulator. With such consideration the operating parameters of the internal combustion engine is thus Diagnostic method according to the invention significantly improved.

In the third embodiment mentioned, the expected pressure and the measured pressure Pressure difference determined, it is from the pressure difference a pressure gradient is determined, it becomes the pressure difference and / or the pressure gradient with a threshold value compared, and the pressure control valve is considered defective detected when the pressure difference and / or the pressure gradient exceeds the threshold.

It is particularly advantageous if that Pressure control valve opened in a linear manner or  is closed so that the pressure difference and / or the Pressure gradient are approximately constant.

Other features, applications and advantages of the Invention result from the following description of embodiments of the invention shown in the figures the drawing are shown. Thereby everyone described or illustrated features for themselves or in any combination the subject of the invention, regardless of their summary in the Patent claims or their relationship and independently from their formulation or representation in the description or in the drawing.

Embodiments of the invention

Fig. 1 is a schematic illustration showing an embodiment of a fuel supply system according to the invention,

FIG. 2 shows a schematic block diagram of an exemplary embodiment of a method according to the invention for operating the fuel supply system of FIGS. 1, and

FIGS. 3a and 3b are schematic diagrams showing signals of the method of Fig. 2 with an intact and a defective fuel supply system

In FIG. 1, a fuel supply system 1 is illustrated that is intended for use in an internal combustion engine of a motor vehicle. The fuel supply system 1 is a so-called common rail system, which is used in particular in an internal combustion engine with direct injection. Common rail systems of this type are known from both gasoline and diesel internal combustion engines.

The fuel supply system 1 has a pressure accumulator 2 , which is provided with a pressure sensor 3 and a pressure control valve 4 . The pressure accumulator 2 is connected to a high-pressure pump 6 via a pressure line 5 . The high pressure pump 6 is connected to the pressure control valve 4 via a pressure line 8 . Via a pressure line 9 and a filter, the pressure control valve 4 and thus also the high pressure pump 6 is connected to a preferably electric fuel pump 10 , which is suitable for drawing fuel from a fuel tank 11 .

The fuel supply system 1 has four injection valves 13 , which are connected to the pressure accumulator 2 via pressure lines 14 . The injection valves 13 are suitable for injecting fuel into corresponding combustion chambers of the internal combustion engine.

By means of a signal line 15 , the pressure sensor 3 is connected to a control unit 16 , to which a plurality of signal lines other than input lines are further connected. The fuel pump 10 is connected by means of a signal line 17 and the pressure control valve 4 is connected to the control unit 16 via a signal line 18 . Furthermore, the injection valves 13 are connected to the control unit 16 by means of signal lines 19 .

The fuel is pumped from the fuel tank 11 to the high-pressure pump 6 by the fuel pump 10 . With the help of the high-pressure pump 6 , a pressure is generated in the pressure accumulator 2 , which pressure is measured by the pressure sensor 3 and can be set to a desired value by corresponding actuation of the pressure control valve 4 . The fuel is then injected into the combustion chamber of the internal combustion engine via the injection valves 13 .

Among other things, the pressure in the pressure accumulator 2 is essential for the dimensioning of the fuel quantity or fuel mass injected into the combustion chamber. The greater the pressure in the pressure accumulator 2 , the more fuel is injected into the combustion chamber during the same injection time. This pressure in the pressure accumulator 2 can be set and adjusted by the control device 16 .

For this purpose, the control unit 16 controls the pressure control valve 4 in its closed state, so that the high pressure pump 6 and the fuel pump 10 generate an ever increasing pressure in the pressure accumulator 2 . This increasing pressure can be measured by the pressure sensor 3 .

The pressure control valve 4 is controlled with a pulse width modulated signal. A duty cycle TV of 0% results in a completely closed pressure control valve 4 , and with a duty cycle TV of 100%, the pressure control valve 4 is fully open.

There is a defined relationship between the duty cycle TV of the pressure control valve 4 and the pressure in the pressure accumulator 2 . This relationship results from the opening cross section of the pressure control valve 4 , which is set at a certain duty cycle TV. The relationship can be determined in advance for a pressure control valve 4 operating without errors and is stored in the form of a characteristic curve or a map in the control unit 16 . To generate a desired pressure in the pressure accumulator 2 , the pressure control valve 4 is activated on the basis of this relationship. If there are deviations between the desired pressure and the actual pressure measured by the pressure sensor 3 , these deviations are corrected.

In addition to this regulation of the pressure in the pressure accumulator 2 , the output of the regulation is monitored. If the value of the manipulated variable available at this controller output exceeds a predetermined threshold value, the fuel supply system 1 is recognized as "possibly faulty". This leads to the start of a diagnostic method, which is described in three embodiments below.

After the diagnosis process has started, the pressure control valve 4 is actuated in all three embodiments with a pulse-width-modulated signal, the pulse duty factor TV of which has a first value. Then the duty cycle TV is changed from the first to a second value. The range delimited by the first and the second value is selected in such a way that the internal combustion engine does not yet show any deteriorated driving behavior or even misfires of the internal combustion engine occur.

Due to the defined relationship between the duty cycle TV of the pressure control valve 4 and the pressure in the pressure accumulator 2 , the change in the duty cycle TV results in a change in the pressure in the pressure accumulator 2 .

In a first embodiment of the diagnostic method, the pressure in the pressure accumulator 2 can thus be calculated by the control unit 16 which, due to the relationship mentioned, must be present for the second value of the duty cycle TV. If the pressure in the pressure accumulator 2 measured by the pressure sensor 3 deviates substantially from the calculated pressure, the control unit 16 can conclude that the pressure control valve 4 has a fault.

In a second embodiment of the diagnostic method, it is assumed that an intact pressure control valve 4 leads to a likewise linear pressure reaction when the duty cycle TV increases linearly. However, a linear pressure reaction is synonymous with an approximately constant pressure gradient. In contrast, if the pressure control valve 4 is defective, stochastic pressure changes result, so that the resulting pressure gradient is not constant.

In the second embodiment, the pressure gradient of the pressure measured by the pressure sensor 3 in the pressure accumulator 2 is therefore determined. If this pressure gradient shows significant deviations from an approximately constant value, the control unit 16 concludes that the pressure control valve 4 has a fault.

A third embodiment of the diagnostic method is shown in FIG. 2. The signals resulting from this method are shown in FIGS . 3a and 3b. Here, the Fig. 3a 3b refers to an intact pressure control valve 4 and the Fig. A faulty pressure control valve 4. The method shown in FIG. 2 is carried out by the control device 16 .

After the diagnostic method has started, the pulse duty factor TV is set to a first value TV1 of 35% in a block 20, for example. The pressure prist currently measured by the pressure sensor 3 in the pressure accumulator 2 is then measured in a block 21 . This pressure prist is shown in FIGS . 3a and 3b.

From the controller 16, a modeled pressure is prbk determined in a block 22 which takes into account the current operating variables of the internal combustion engine, such as its current speed, the engine temperature and the like. This pressure prbk is shown in FIGS . 3a and 3b.

In a subsequent block 23 , the control unit 16 calculates a pressure difference dpr, for which the following applies: dpr = prbk - prist. The control device 16 then calculates a pressure gradient grddpr for the pressure difference dpr in a block 24 . This pressure difference dpr and this pressure gradient grddpr are also shown in FIGS . 3a and 3b.

The control unit 16 now checks in a block 25 whether the amount of the pressure difference dpr exceeds a threshold value S1. If this is not the case, it is concluded that the pressure control valve 4 is not defective.

In a subsequent block 26, the pulse duty factor TV is then increased by one increment, for example by 1%. The control unit 16 then checks in a block 27 whether the pulse duty factor TV has reached a second value TV2 of, for example, 45%. If this is not the case, the diagnostic method is continued with block 21 and the measurement of the pressure prist is repeated. If the second value TV2 of the duty cycle TV is reached, the diagnostic process is ended.

FIG. 3a is an intact pressure control valve 4 is based. So that z. B. for the value TV1 of the duty cycle TV, the pressure difference dpr between the measured pressure prist and the modeled pressure prbk is relatively small. In any case, the amount of the pressure difference dpr is smaller than the threshold value 51 . As a result, the diagnostic method of FIG. 2 runs through blocks 21 to 27 in succession.

If the duty cycle TV is then incremented, nothing essential changes in the above pressure difference dpr. Furthermore, the amount of the pressure difference dpr remains smaller than the threshold value 51 and blocks 21 to 27 continue to be run through. This is repeated until the value TV2 of the duty cycle TV is reached.

In FIG. 3a this results in a linearly increasing measured pressure prist and a linearly increasing modeled pressure prbk. On account of the current operating variables of the internal combustion engine, the slope of the modeled pressure prbk is approximately equal to the slope of the measured pressure prist. The pressure difference dpr thus remains relatively small. In any case, the pressure difference dpr in the intact pressure control valve 4 of FIG. 3a always remains smaller than the threshold value S1.

The control unit 16 can thus correctly conclude that the pressure control valve 4 is intact by means of the method in FIG. 2 in FIG. 3a.

If, during one of the repetitions of the run through the blocks 21 to 27, the amount of the pressure difference dpr exceeds the threshold value S1, this is determined in block 25 by the control device 16 . The method of FIG. 2 then continues with a block 28 with which an observation time period Z is started.

In a subsequent block 29 , the control unit 16 checks whether the magnitude of the pressure gradient grddpr exceeds a threshold value S2. If this is the case, the control unit 16 concludes that the pressure control valve 4 has an error and the diagnostic method in FIG. 2 is ended.

This case of the defective pressure control valve 4 is shown in FIG. 3b. There, the course of the measured pressure prist in the pressure accumulator 2 has a significant drop, which is identified by reference numeral 40 . This slump can result, for example, from a jamming of the pressure control valve 4 due to contamination. The result of the drop 40 is that the pressure difference dpr also has a relatively large deflection, which is identified by the reference number 41 .

The same applies to the pressure gradient grddpr, which also has a relatively large deflection 42 .

The amount of the pressure difference dpr is larger than the threshold S1 in the area of the deflection 41 . This achieves block 28 of the method of FIG. 2. The amount of the pressure gradient in the area of the deflection 42 is also greater than the threshold value S2. It is thus recognized by block 29 of FIG. 2 that the pressure control valve 4 is defective.

If the amount of the pressure difference dpr is greater than the threshold value S1, but the amount of the pressure gradient grddpr is less than the threshold value S2, the observation period Z is increased in a block 30 , e.g. B. incremented. In a subsequent block 31 , the control unit 16 checks whether the observation period Z has reached a maximum value ZM.

If this is the case, the method of FIG. 2 is continued with block 26 and thus ultimately with the repetitions of blocks 21 to 27 . This can occur if the amount of the pressure difference dpr has exceeded the threshold value S1 for an intact pressure control valve 4 due to incomprehensible reasons and at least the appearance of a defective pressure control valve 4 has thus been generated. Block 29 then checks whether there is actually a fault in the pressure control valve 4 . If this is not the case up to the expiry of the maximum value ZM of the observation time period Z, then the test of the pressure control valve 4 described at the beginning is repeated using block 25 .

If the control unit 16 determines in block 31 of FIG. 2 that the maximum value ZM has not yet been reached, the duty cycle is increased in a block 32 , e.g. B. incremented by 1%. It is then checked in a block 33 whether the second value TV2 of the duty cycle TV has been reached. If this is the case, the method of FIG. 2 is ended. To this extent, blocks 32 and 33 correspond to blocks 26 and 27 .

If the second value TV2 of the duty cycle TV has not yet been reached, the current pressure prist in the pressure accumulator 2 is successively measured in block 34 with the aid of the pressure sensor 3 , the modeled pressure prbk is determined as a function of the current operating variables of the internal combustion engine, and that Pressure difference dpr and the pressure gradient grddpr are calculated. To this extent, block 34 represents a summary of blocks 21 , 22 , 23 , 24 .

After block 34 , the method of FIG. 2 is continued with block 29 and thus with the comparison of the amount of the pressure gradient grddpr with the threshold value S2. The blocks 29 to 34 are then repeated until either an error in the pressure control valve 4 is recognized by the control unit 16 , or the maximum value ZM of the observation period Z is reached or the second value TV2 of the duty cycle TV is reached.

Overall, an error of the pressure control valve 4 is recognized with the diagnostic method of FIG. 2 if and only if the amount of the pressure difference dpr and the amount of the pressure gradient grddpr exceed associated threshold values S1, S2. If one of the threshold values S1, S2 is not exceeded, the control unit 16 determines the functionality of the pressure control valve 4 .

Claims (13)

1. Method for operating a fuel supply system ( 1 ) for an internal combustion engine, in particular a motor vehicle, in which fuel is pumped by a pump ( 6 , 10 ) into a pressure accumulator ( 2 ), in which the pressure (prist) in the pressure accumulator ( 2 ) is measured, and at which the pressure (prist) in the pressure accumulator ( 2 ) can be changed by the control of a pressure control valve ( 4 ), characterized in that the pressure control valve ( 2 ) is controlled such that an expected pressure (prbk) is in should result in the pressure accumulator ( 2 ), and that the functionality of the pressure control valve ( 4 ) is inferred from the expected pressure (prbk) and from the measured pressure (prist). 2. The method according to claim 1, characterized in that the expected pressure (prbk) and the measured pressure (prist) are compared with each other, and that the pressure control valve ( 4 ) is recognized as defective when the measured pressure (prist) is significantly different from that expected value (prbk) differs. 3. The method according to claim 1, characterized in that an expected pressure gradient is determined from the expected pressure, that a measured pressure gradient is determined from the measured pressure, that the expected pressure gradient is compared with the measured pressure gradient, and that the pressure control valve ( 4 ) is recognized as defective if the measured pressure gradient deviates significantly from the expected pressure gradient. 4. The method according to claim 3, characterized in that the pressure control valve ( 4 ) is opened or closed in a linear manner, and that the expected pressure gradient is approximately constant. 5. The method according to claim 1, characterized in that the expected pressure (prbk) depending on Operating variables of the internal combustion engine, in particular in Dependence on the speed of the internal combustion engine is determined. 6. The method according to claim 5, characterized in that from the expected pressure (prbk) and the measured pressure (prist) a pressure difference (dpr) is determined. 7. The method according to claim 6, characterized in that a pressure gradient (grddpr) from the pressure difference (dpr) is determined. 8. The method according to any one of claims 6 and / or 7, characterized characterized in that the pressure difference (dpr) and / or the Pressure gradient (grddpr) with a threshold (S1, S2) is compared. 9. The method according to claim 8, characterized in that the pressure control valve ( 4 ) is recognized as defective if the pressure difference (dpr) and / or the pressure gradient (grddpr) exceeds the threshold value (S1, S2). 10. The method according to any one of claims 6 to 9, characterized in that the pressure control valve ( 4 ) is opened or closed in a linear manner, and that the pressure difference (dpr) and / or the pressure gradient (grddpr) are approximately constant. 11. Electrical control element, in particular flash memory or read-only memory, for a control unit ( 16 ) of an internal combustion engine, in particular a motor vehicle, on which a program is stored which can be run on a computing device, in particular on a microprocessor, and for executing a Method according to one of claims 1 to 10 is suitable. 12. Control unit ( 16 ) for a fuel supply system ( 1 ) of an internal combustion engine, in particular a motor vehicle, wherein in the fuel supply system ( 1 ) fuel can be pumped by a pump ( 6 , 10 ) into a pressure accumulator ( 2 ), the pressure (prist) in the pressure accumulator ( 2 ) can be measured, and the pressure (prist) in the pressure accumulator ( 2 ) can be controlled such that an expected pressure (prbk) in the pressure accumulator ( 2 ) should result, characterized in that the control device ( 16 to TV2) is), the pressure control valve (2) to a predetermined value (TV1 controllable to an expected pressure by the control device (16) (prbk) can be determined in the pressure accumulator (2), and that by the controller (16) from the expected pressure (prbk) and from the measured pressure (prist) the functionality of the pressure control valve ( 4 ) can be concluded. 13. Fuel supply system ( 1 ) for an internal combustion engine, in particular of a motor vehicle, in which fuel can be pumped by a pump ( 6 , 10 ) into a pressure accumulator ( 2 ), in which the pressure (prist) in the pressure accumulator ( 2 ) can be measured, and in which the pressure (prist) in the pressure accumulator ( 2 ) can be controlled such that an expected pressure (prbk) in the pressure accumulator ( 2 ) should result, and with a control device, characterized in that the control device ( 16 ) the pressure control valve (2) (to TV2 TV1) is controllable to a predetermined value, that an expected pressure by the control device (16) (prbk) can be determined in the pressure accumulator (2), and that expected from by the control device (16) Pressure (prbk) and from the measured pressure (prist) on the functionality of the pressure control valve ( 4 ) can be concluded.