The invention relates to a method for operating a fuel injection system, in particular a common rail injection system, for supplying a combustion engine of a vehicle with fuel. Moreover, the invention relates to an electronic control unit.
A fuel injection system, in particular a common rail injection system, for supplying a combustion engine of a vehicle with fuel comprises a high-pressure pump by means of which fuel can be conveyed at high pressure and fed to a high-pressure accumulator of the system, the so-called “rail”. At least one injector is connected to the high-pressure accumulator in order to remove fuel from the high-pressure accumulator and inject it into a cylinder of the combustion engine. The removal of fuel from the high-pressure accumulator is noticeable by a pressure drop which can be re-equilibrated by the conveyance operation of the high-pressure pump. Further factors that affect the pressure in the high-pressure accumulator are properties of the fuel, in particular its quality and temperature, because they affect the compressibility of the fuel. A pressure sensor is therefore typically integrated into the high-pressure accumulator in order to monitor the pressure.
A high-pressure pump arranged in a fuel injection system, in particular in a common rail injection system, can comprise one or more pump elements. Each pump element typically has a liftable pump piston supported via a roller plunger on a camshaft of the pump. When the camshaft rotates, the roller of the roller plunger runs off circumferentially on the cam. On the other end, the roller plunger is received in a cylinder bore of the pump housing such that the rotation of the camshaft is converted into a stroke movement of the pump piston. Damage to the drive can occur due to a misalignment of the roller of the roller plunger relative to the cam of the camshaft due to increased wear and/or a sticking of the roller. This can result in the fuel supply of the combustion engine becoming unavailable and the vehicle breaking down. If the vehicle is used for business purposes, a high level of economic damage can be associated with the failure of the vehicle. There is therefore an interest in an early detection of any damage to the drive in order to prevent a breakdown of the vehicle by visiting a service station in a timely manner.
In particular, the proposed method can comprise method steps which, in a different context, have already been described in DE 10 2017 212 762 A1, which is an earlier application of the same applicant. Reference is therefore made to this earlier application, in particular with regard to the method steps of detecting a pressure (P) in the high-pressure accumulator in an angle-synchronous manner, as well as determining a frequency-transformed spectrum (DFT(P)) of the sensed pressure (P), which are in particular described in further detail in paragraphs [0007] and [0009] of the earlier application.
In the proposed method for operating a fuel injection system for supplying a combustion engine of a vehicle with fuel, the fuel is conveyed at high pressure with the aid of a high-pressure pump, fed to a high-pressure accumulator, and injected into a cylinder of the combustion engine with the aid of at least one injector connected to the high-pressure accumulator. According to the invention, the method comprises steps a) to c) for detecting any damage to the drive of the high-pressure pump. In step a), the pressure (P) in the high-pressure accumulator is measured and, on the basis of the measured values, a pressure drop (ΔP) in the high-pressure accumulator caused by an injection into a cylinder is determined. In step b) a maximum pressure gradient is determined during a pressure build-up phase following the injection. In step c), the pressure drop (ΔP) determined in step a) and the maximum pressure gradient determined in step b) are put into proportion.
Insofar as damage to the drive of the high-pressure pump is present, this has an impact on the pressure build-up in the high-pressure accumulator. In the event of damage, the wear in the contact region between the roller plunger and the cam increases, so that the pump piston of the corresponding pump element can no longer carry out a full stroke. With the aid of the proposed method, this effect can be visualized, because the graph runs flatter when one puts the parameters determined in step a) and b) of the method into proportion.
The effects of damage to the drive on the pressure in the high-pressure accumulator are primarily or exclusively seen in the pressure build-up phase. The situation is different for a change of the influencing factors mentioned above, for example fuel quality and/or fuel temperature. These affect the pressure in the high-pressure accumulator both during the pressure drop and during the pressure build-up. The curve representing the pressure profile is therefore merely compressed or pulled apart. In combination with the maximum pressure gradient according to step c) of the proposed method, there is no change in the profile of the graph. If, however, a changed profile is shown, this can only be attributed to damage to the drive of the high-pressure pump.
Accordingly, with the aid of the proposed method, damage to the drive of the high-pressure pump can be detected, so that a service station can be approached before the vehicle breaks down.
Preferably, in step a) of the proposed method, the pressure (P) in the high-pressure accumulator is measured angle-synchronously, in particular continuously, with the aid of a pressure sensor arranged on the high-pressure accumulator. The measurement is carried out angle-synchronously, that is to say, as a function of the angle of rotation of a crankshaft of the combustion engine.
Further preferably, in step a) of the proposed method, the pressure drop (ΔP) in the high-pressure accumulator is determined with the aid of discrete Fourier transformation (DFT) on a cylinder-specific basis. That is to say, the pressure drop determined in step a) refers to a particular cylinder frequency and is thus due to an injection into that one cylinder.
Furthermore, preferably in step b) of the proposed method, the maximum pressure gradient is determined from the first derivative of the pressure (P) measured in step a). The parameters determined in step a) and step b) can thus be combined.
In order to detect damage to the drive of the high-pressure pump, steps a) to c) are preferably carried out repeatedly. The repeated execution allows the results to be compared over a longer period of time. This is because the increased wear in the contact region between the roller plunger and the cam associated with damage to the drive does not usually occur all at once, but gradually. The observation over a longer period of time allows minor changes to be shown, so that damage to the drive can be detected early.
With the help of the proposed method, a “state of health” statement can in particular be made with regard to the high-pressure pump, which allows damage to be detected early. If damage is detected, a service station can be approached in a timely manner so that a breakdown of the vehicle is prevented. In addition to the pressure measurement in step a) of the proposed method, steps b) and c) are also preferably carried out on board the vehicle, so that a current state of health statement can be made.
Preferably, at least steps b) and c) are carried out with the aid of an electronic control unit. The controller is provided with the measured values that reflect the pressure (P) in the high-pressure accumulator for this purpose. Based on these measured values, the pressure drop (ΔP) and maximum pressure gradient parameters can be determined. The measured values are preferably obtained by the control unit from a pressure sensor arranged on the high-pressure accumulator. With the aid of the control unit, which can in particular be a control unit of the combustion engine, the pressure profile can be continuously monitored. Furthermore, by pairing the pressure drop and maximum pressure gradient parameters derived from the measured values, an analysis can be carried out with respect to the “state of health” of the high-pressure pump.
Upon detection of damage to the drive of the high-pressure pump, a warning signal is preferably output to the driver of the vehicle and/or to an external control station connected to the vehicle via a communication interface. The driver can then approach a service station and have the damage fixed. At the control station, corresponding information from a plurality of vehicles can be collected and evaluated. Furthermore, the availability of a further vehicle can be checked. The warning signal can be an optical and/or acoustic warning signal. The visual warning signal can in particular be displayed via a display in the vehicle and/or in the control station.
Because an electronic control unit is preferably used in the performance of the method, an electronic control unit is also proposed, which is configured so as to carry out steps of a method according to the invention. The electronic control unit can in particular be the control unit of the combustion engine. Because it controls the injections into the cylinders of the combustion engine, it generally already has the measured values required to carry out the method at its disposal. The device-related expense can thus be kept minimal.
Moreover, a computer program having a computer program code is proposed, which carries out steps of a method according to the invention when the computer program is run on a processor. This can in particular be a processor integrated into an electronic control unit.
Furthermore, a machine-readable storage medium having the computer program according to the present invention stored thereon is proposed. For example, the machine-readable storage medium can be an external or internal memory, in particular an internal memory of an electronic control unit.
The invention will be explained in more detail in the following with reference to the accompanying drawings. The figures show:
Other factors that can affect the pressure in the high-pressure accumulator 3 are, for example, the fuel quality and fuel temperature, because these factors change the compressibility of the fuel. A change of these factors affects both the pressure drop and the subsequent pressure build-up in the high-pressure accumulator 3. This is illustrated by way of example in
As shown in
A similar graph showing the ratio of pressure drop to maximum pressure gradient can be seen in
The result is different when the high-pressure pump 3 has damage to the drive. This is shown in
Independently of
Number | Date | Country | Kind |
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10 2021 202 096.8 | Mar 2021 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2022/052992 | 2/8/2022 | WO |