The present invention relates to methods for operating an internal combustion engine having a common-rail injection system, in particular, based on a quantity of fuel to be ascertained. In addition, the present invention relates to methods for modeling the quantity of fuel injected in an internal combustion engine having a common-rail injection system.
In internal combustion engines having a common-rail injection system, fuel from a high-pressure reservoir is injected through injection valves into the cylinders, directly into the combustion chambers of the cylinders.
At present, the fuel quantity injected is determined based on the rail-pressure characteristic in the high-pressure reservoir, using valve lifts and opening times of the injection valves. These parameters, and also further parameters, in particular, component parameters, are encumbered by high tolerances. In order to compensate for these tolerances, in particular, over the service life, the quantity injected should be estimated with the aid of the rail-pressure characteristic, although the rail-pressure characteristic is also subjected to some tolerances. Thus, there are manufacturing tolerances in the volume of the common-rail injection system, tolerances in the fuel characteristics that are a function of the type of fuel, and measuring tolerances in the measurement of the fuel temperature and the rail pressure. Therefore, quantity estimation methods based on rail pressure have high tolerances irrespective of the manner of determining the quantity of fuel injected. Consequently, the quantity of fuel injected may not easily be determined by a physical model in a reliable manner.
For example, German Patent Application No. DE 10 2005 006 361 A1 describes a method for operating an internal combustion engine, where the fuel is fed at least intermittently into a fuel manifold, to which at least one injector is connected, and where a pressure difference, which occurs in the fuel manifold during at least one injection, is measured. To measure the pressure difference, the fuel manifold is assumed to be an essentially closed system, and the pressure difference is detected in a time-based manner.
German Patent Application No. DE 10 2014 215 618 A1 relates to a method for determining a quantity of fuel injected, which is extracted from a high-pressure reservoir and injected into one or more combustion chambers of an internal combustion engine. The characteristic of the fuel pressure in the high-pressure reservoir is measured, and a characteristic of the fuel pressure transformed by frequency is ascertained. The quantity injected is ascertained from a component belonging to the ignition frequency of the internal combustion engine, in the characteristic of the fuel pressure transformed by frequency.
German Patent Application No. DE 10 2004 031 006 A1 describes a method for determining at least one quantity of fuel injected in an internal combustion engine having a common-rail injection system, with the aid of a rail-pressure sensor and an engine control unit having an artificial neural network. The neural network is used, in order to allow a quantity injected to be determined from rail-pressure data in real time. To that end, absolute values of the rail-pressure characteristic are ascertained and supplied to the neural network as an input variable vector.
The present invention provides a method for operating an internal combustion engine having a common-rail injection system, as well as a device and an engine system.
Example embodiments and refinements of the present invention are described herein.
According to a first aspect of the present invention, a method for operating an internal combustion engine having a common-rail injection system, as a function of a quantity of fuel injected, is provided. In accordance with an example embodiment of the present invention, the method include the following steps:
The above example method for operating the internal combustion engine is based on a determination of a quantity of fuel injected as a function of a characteristic of a fuel pressure in a high-pressure reservoir of the common-rail injection system (rail-pressure characteristic). This characteristic of the fuel pressure is subjected to several tolerances. The modeling is accomplished, using a trainable model, in particular, with the aid of a nonparametric model, such as a Gaussian process model, and/or a neural network. A main feature of the above method is to configure the model in such a manner, that it is as independent as possible of the tolerances of the parameters encumbered by tolerances. The dependence of the pressure drop Δp in the high-pressure reservoir that results due to the injection of a quantity of fuel is:
for the injected volume of fuel ΔV and
for the injected mass of fuel Δm.
Consequently, the quantity of fuel injected may be specified as a volume-based quantity of fuel injected ΔV or as a mass-based quantity of fuel injected Δm.
It is apparent that the factor
includes quantities encumbered by tolerances, such as an absolute rail pressure p in the high-pressure reservoir, a fuel temperature T in the high-pressure reservoir, and a storage volume V of the high-pressure reservoir, as well as a compressibility K or c2.
During training of a nonparametric model, the variables encumbered by tolerances must be simulated in their possible tolerance ranges, in order to obtain appropriate training data for the model to be modeled. This is cumbersome, and therefore, in accordance with an example embodiment of the present invention, it is provided that the quantity of fuel injected be estimated based on only a characteristic of the relative pressure in the high-pressure reservoir, and that no other parameters relevant to the structure of the high-pressure reservoir and the fuel stored in it be considered in the training method. In particular, consideration of the variables of the absolute pressure, the temperature, and the volume of the high-pressure reservoir, as well as the compressibility of the fuel as a function of the type of fuel used, should be explicitly dispensed with.
Training of the nonparametric model based on only the relative-pressure characteristic of the rail pressure may be carried out in a highly simple manner, and consequently, in a very short time on the test stand, it is possible to adapt the model to the individual combustion engine. The consideration of the relative-pressure characteristic independent of the above-mentioned parameters allows the influences of the individual, tolerance-encumbered parameters to be learned so as to be subsumed in the relative-pressure characteristic, which means that it is possible to estimate the quantity of fuel injected by suitably formulating an input variable vector, which describes the characteristic of the relative pressure in the high-pressure reservoir.
In addition, the relative-pressure characteristic may be determined as a function of a reference rail pressure, which is derived as a mean or initial value of a rail-pressure characteristic in a current or preceding operating cycle of the internal combustion engine.
According to one specific embodiment of the present invention, the quantity of injected fuel may be determined as a function of a pressure difference between a maximum rail pressure and a minimum rail pressure.
Furthermore, the information item about the relative-pressure characteristic may be specified as a relative-pressure characteristic information item, which represents at least a part of an input variable vector for the trained functional model.
In particular, the relative-pressure characteristic information item may include one or more of the following information items:
Furthermore, the quantity injected may additionally be determined, using an engine speed information item, which corresponds, in particular, to an average speed of the internal combustion engine during the current operating cycle, or using a load information item.
Specific embodiments of the present invention are explained in greater detail below, on the basis of the figures.
In addition, high-pressure reservoir 42 is connected to an adjustable pressure-regulating valve 45, in order to adjust a rail pressure in high-pressure reservoir 42, that is, the pressure of the fuel in high-pressure reservoir 42, to a predefined setpoint rail pressure. To control the rail pressure, fuel may be supplied to high-pressure reservoir 42 by high-pressure pump 43 and fed back to fuel tank 5 via pressure-regulating valve 45.
The control of engine system 1 is carried out by an engine control unit 10, which, in order to control the internal combustion engine, acquires sensor signals and outputs appropriate actuating signals to actuators of engine system 1. Thus, engine control unit 10 measures the rail pressure, using a rail-pressure sensor 46 in high-pressure reservoir 42.
In addition, engine control unit 10 controls actuators of engine system 1 on the basis of actuating variables and on the basis of a predefined setpoint engine torque, which may be ascertained, for example, from an inputted torque desired by the driver.
Apart from other functions, engine control unit 10 includes a function for ascertaining a quantity of fuel injected. The quantity of fuel injected is needed for operating engine system 1, since a set engine torque may be derived and/or ascertained from it. In addition, this may be used for checking the plausibility of, and adapting, the function of the injection valves, in order to be able to adjust the actual quantity of fuel injected more accurately.
The quantity of fuel injected may be ascertained by a trained, parameter-free functional model, from a pressure characteristic of the rail pressure in high-pressure reservoir 42. The trained functional model may be, for example, a nonparametric functional model, such as a Gaussian process model or a neural network. In general, the following equation is yielded for the quantity of fuel injected:
as a volume-based quantity of fuel injected ΔV (volume of fuel injected) and
as a mass-based quantity of fuel injected Δm (mass of fuel injected).
In this context, p corresponds to the absolute rail pressure in high-pressure reservoir 42, Δp corresponds to a drop in the rail pressure (pressure difference) caused by the injection, T corresponds to a fuel temperature in high-pressure reservoir 42, V corresponds to a storage volume of high-pressure reservoir 42, and K and/or c2 corresponds to a compressibility of the fuel as a function of rail pressure p and fuel temperature T. Function K or c2 reflects the compressibility of the fuel, which may be a function of the type of fuel.
The determination of the type of fuel, the determination of absolute rail pressure p, the determination of fuel temperature T in high-pressure reservoir 42, as well as the determination of actual volume V of high-pressure reservoir 42 are encumbered by tolerances; in particular, the determination of absolute rail pressure p being highly error-prone. The use of a physical model, which reflects the above relationship, is not considered, since errors in the different parameters may increase and, thus, result in unusable model values for injected fuel quantities to be determined.
Therefore, in accordance with an example embodiment of the present invention, it is provided that with the aid of a trainable functional model, the entire factor
between the pressure difference and the fuel quantity be determined according to the above-mentioned formula. A functional model may indeed be trained for the factor X, which is a function of the parameters type of fuel, absolute rail pressure p, fuel temperature T in high-pressure reservoir 42, and the volume of high-pressure reservoir 42, but for taking tolerances into account, not all of the above-mentioned parameters may be varied on a test stand, in order to cover all possible system states. In particular, the deliberate variation of storage volume V of high-pressure reservoir 42 is difficult to accomplish, since this would entail the removal and installation of different high-pressure reservoirs. In addition, varying the type of fuel over all fuels found in practical operation is highly burdensome.
It has been determined that pressure characteristic p in high-pressure reservoir 42 reflects the influences of the parameters mentioned above. This occurs independently of the absolute rail pressure in high-pressure reservoir 42. Consequently, a trainable functional model may be trained with the aid of pressure variation, that is, a pressure-change characteristic based on an absolute reference pressure; the absolute reference pressure value being able to correspond to an average pressure value of a preceding operating cycle or to a cycle entrance pressure (as the first rail-pressure value of the current operating cycle). The operating cycle relates to four-stroke operation of a cylinder and corresponds to two revolutions of the crankshaft and/or a period of time needed for them.
While the measurement of absolute rail pressure p in high-pressure reservoir 42 may be highly error-prone, measurements of the pressure fluctuations of rail pressure p, that is, of the relative-pressure characteristic, may be taken relatively accurately and error-free. In addition, such a pressure-change characteristic of the rail pressure in high-pressure reservoir 42 reflects the physical conditions of common-rail injection system 4 effectively and also exhibits a decreased error. In particular, the trained functional model is provided in such a manner, that it only processes information items about the relative pressure characteristic of the rail pressure in high-pressure reservoir 42, but not information items regarding the type of fuel, absolute rail pressure p, fuel temperature T and volume V of high-pressure reservoir 42. From the outset, this prevents error-prone variables from being included in the learning operation for the trainable functional model.
A flow chart capable of being implemented in engine control unit 10 in accordance with a specific embodiment is represented in
In a rail-pressure storage block 11, a characteristic curve of rail pressure p is recorded at least for the current operating cycle, using rail-pressure sensor 46, and stored in a suitable manner. In addition, the engine speed or another load information item of internal combustion engine 2 may be stored in an engine-speed storage block 12.
In a pressure-change characteristic block 13, the stored characteristic of absolute rail pressure p is processed, in order to obtain a relative-pressure characteristic of rail pressure p. This may take place on the basis of the absolute reference rail pressure, which corresponds to an average value of the rail pressure during one or more operating cycles, a value of absolute rail pressure p at the beginning of the current operating cycle, or a maximum value of rail pressure p during the operating cycle.
In a differential pressure block 14, pressure difference Δp between a maximum rail pressure pmax and a minimum rail pressure pmin within an operating cycle may be ascertained (see
In addition, the relative-pressure characteristic is processed in a characteristic specification block 15, in order to describe the relative-pressure characteristic in a suitable manner for processing in the functional model. In this context, the relative-pressure characteristic is provided as a relative-pressure characteristic information item. In this context, a suitable compromise should be adopted between the number of supplied input variables and the degree of detail of the description of the relative-pressure characteristic. A relative-pressure characteristic information item is available as a result of characteristic specification block 15.
Together with an engine-speed information item, which corresponds, for example, to an average engine speed of internal combustion engine 2 during the current operating cycle, or to another load information item, the relative-pressure characteristic information item may now be provided as an input variable vector for a functional model block 16. The functional model implemented in functional model block 16 now determines factor X on the basis of the relative-pressure characteristic represented by the input variable vector.
Consequently, in functional model block 16, in which the nonparametric functional model, such as the Gaussian process model or the neural network, is implemented, factor X is derived from the relative-pressure characteristic information item.
Now, in a division block 17, the differential pressure may be divided by the particular factor X, in order to obtain the quantity of fuel injected ΔV, Δm.
The relative pressure characteristic of rail pressure p in high-pressure reservoir 42 may be indicated by the relative-pressure characteristic information item in different ways, which may be used separately or in combination in the form of the relative-pressure characteristic information item of the input variable vector for the trainable functional model:
A flow chart capable of being implemented in engine control unit 10 in accordance with a further specific embodiment is represented in
The components corresponding to the specific embodiment of
To train the trainable functional model, a factor X, which results from an actual quantity of fuel injected and a differential pressure between a maximum pressure and a minimum pressure of the relative-pressure characteristic, in particular, as a quotient, is learned on a test stand for different operating points of the internal combustion engine, in particular, at different engine speeds and load torques and in the case of the respective relative-pressure characteristic information item. The actual quantity of fuel injected may be calculated from the engine torque with the aid of conventional models.
Number | Date | Country | Kind |
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102018213114.7 | Aug 2018 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2019/067846 | 7/3/2019 | WO | 00 |