EP2422066A1 - Method for operating an injection valve - Google Patents

Abstract

The invention relates to a method for operating an injection valve (18a), in particular of a combustion engine (10) of a motor vehicle, wherein a component of the injection valve (18a), in particular a valve needle (28), is driven by means of an electromagnetic actuator (26, 30). According to the invention, depending on at least one electrical operating variable of the electromagnetic actuator (26, 30), a variable is formed which characterizes the acceleration of a moveable component of the electromagnetic actuator, in particular of an armature (30) of the electromagnetic actuator, and, depending on the variable characterizing the acceleration, an operating state of the injection valve (18a) is concluded.

Description

 description

title

Method for operating an injection valve

State of the art

The invention relates to a method for operating an injection valve, in particular an internal combustion engine of a motor vehicle, in which a component of the injection valve, in particular a valve needle, is driven by means of an electromagnetic author.

Disclosure of the invention

It is an object of the present invention to provide an improved method of operation of the type mentioned, in which precise information about an operating state of the injector without the use of additional, the injection valve monitoring, sensors are obtained.

This object is achieved in the operating method of the type mentioned in the present invention that in dependence on at least one electrical operating variable of the electromagnetic actuator, the acceleration of a movable component of the electromagnetic actuator, in particular a magnet armature of the electromagnetic actuator, characterizing size is formed, and that in dependence the quantity characterizing the acceleration is related to an operating condition of the

Injector is closed.

According to the invention, it has been recognized that, in a plurality of different operating states or transitions between these operating states, the acceleration of a movable component of the electromagnetic actuator, in particular of the magnet armature, characterizing size has a value characterizing the operating state or the state transition and / or time characteristic, so that precise information about an operating state of the injection valve can be obtained from the consideration according to the invention of the variable characterizing the acceleration.

In contrast to conventional methods, which are primarily concerned with an evaluation of a speed of a movable component, the acceleration-based method according to the invention advantageously makes it possible to obtain information about one

Operating state of the injector even when the power transmission from the electromagnetic actuator to the valve needle by means of a complex mass system, which does not provide a simple, rigid mechanical coupling between the armature and the valve needle.

According to investigations by the Applicant, due to the different interactions of individual components of a mass system containing the valve needle and the magnet armature, characteristic values or time courses for a variable characterizing the acceleration result, so that advantageously conclusions about the operating state of the injection valve are drawn with great precision can.

In a particularly advantageous embodiment of the method according to the invention, the valve needle, preferably in a closing direction of the valve needle, spring-loaded, the armature is connected to the valve needle, that the armature relative to a direction of movement of the valve needle with a non-disappearing mechanical clearance is movable relative to the valve needle , And from a characteristic feature of the acceleration of the armature characterizing magnitude is concluded that the armature detaches from the valve needle.

In this configuration according to the invention, the impact of the valve needle on its associated valve seat (closing time) can be determined particularly advantageous, because in this case the armature of the valve needle below

Exploitation of the existing mechanical game triggers, resulting in a corresponding acceleration change of the armature reflected. This change in acceleration of the armature results in the present embodiment of the operating method according to the invention in that after releasing the armature of the valve needle, the still spring-loaded valve needle no longer force on the

Magnetic anchor exercises. The armature moves itself accordingly in contrast to the valve needle initially in the closing direction, but henceforth with a lower acceleration. Conventional methods based solely on the evaluation of the speed of the magnet armature do not allow the detection of the present invention in the present configuration

Close timing. By contrast, the method according to the invention, by utilizing the variable characterizing the acceleration of the magnet armature, enables precise information as to when the magnet armature releases itself from the valve needle or when the valve needle has reached its closed position in the region of the valve seat.

In a further preferred embodiment of the operating method according to the invention is used as the electrical operating variable of the electromagnetic actuator applied to a solenoid coil of the electromagnetic actuator actuator voltage, and the first time derivative of the actuator voltage is formed as the acceleration of the armature characterizing size. For example, it can advantageously be concluded from the occurrence of a local minimum of the first time derivative of the actuator voltage that the magnet armature is released from the valve needle.

A particularly simple and reliable evaluation of the size characterizing the acceleration is, according to a further advantageous variant of the invention, possible if an actuator current flowing through the magnet coil is impressed to a predeterminable value. Particularly advantageous is a temporally constant actuator current, more preferably also a vanishing actuator current, impressed.

As an alternative to the use of the actuator voltage described above, it is also possible to use an actuator current flowing through a magnet coil of the electromagnetic actuator in order to determine the acceleration of the actuator Magnetankers characterizing size, in this case the first time derivative of the Aktorstroms to determine.

In a further advantageous embodiment of the operating method according to the invention, it is concluded from the occurrence of a local maximum of the first time derivative of the actuator current that the magnet armature is released from the valve needle.

As an alternative or in addition to the above-described consideration of local extremes of the variable characterizing the acceleration, it is also possible to compare a time profile of the variable characterizing the acceleration with a predetermined reference curve or also other features such as a bend over time or the like identify.

A particularly precise determination of the operating state of the injector is again given when - in the case of detecting the actuator current - an applied to the solenoid of the electromagnetic actuator actuator voltage to a predetermined value, in particular zero, impressed, which by a corresponding control of the injection valve can be accomplished by controlling ECU final stage.

In a further very advantageous variant of the invention, it is provided that a first electrical operating variable of the electromagnetic actuator is detected and supplied to an observer member, which transmits the electromagnetic actuator without

Taking into account the retroactivity of an armature movement to electrical operating variables of the electromagnetic actuator, wherein the observer member determines an observed second electrical operating variable of the electromagnetic actuator that the observed second electrical operating variable is compared with a detected second electrical operating variable, and that the acceleration characterizing variable in dependence of the comparison result.

According to the invention it has been recognized that the comparison result obtained using the observer member has significant information about an operating state of the injection valve and therefore advantageous for Determination of opening and / or closing times of the injection valve can be used.

In contrast to conventional methods, which alone an "electric" opening time or closing time by evaluating the

Control variables of the injection valve or its electromagnetic actuator can determine the operating method according to the invention by the evaluation of the acceleration characterizing magnitude of the precise determination of an actual hydraulic opening or closing time, in which the valve needle lifts from its closing seat and again impinges on its closing seat.

Of particular importance is the realization of the operating method according to the invention in the form of a computer program which can be stored on an electronic or optical storage medium and which is controlled by a control and / or regulating device, e.g. is executable for an internal combustion engine.

Further advantages, features and details will become apparent from the following description in which, with reference to the drawings, various embodiments of the invention are shown. The features mentioned in the claims and in the description may each be essential to the invention individually or in any desired combination.

In the drawing shows:

1 shows a schematic representation of an internal combustion engine with a plurality of injection valves operated according to the invention, FIG.

FIGS. 2a to 2c schematically show a detail view of an injection valve from FIG. 1 in three different operating states,

FIG. 3 shows a simplified flow chart of an embodiment of the method according to the invention, FIG. 4 shows a time profile of operating variables of the injection valve considered according to the invention;

FIG. 5 shows a further time course according to the invention

Operating variables of the injection valve,

Figure 6 is a simple electrical equivalent circuit diagram of the electromagnetic

Actuator of the injection valve according to Figure 2a,

FIG. 7 shows a block diagram corresponding to the equivalent circuit diagram according to FIG. 6, and FIG

8 shows a block diagram of a method for determining a correction variable using an observer member according to FIG. 7.

In FIG. 1, an internal combustion engine bears the reference numeral 10 as a whole. It comprises a tank 12, from which a delivery system 14 delivers fuel into a common rail 16. To this several electromagnetically operated injection valves 18a to 18d are connected, which inject the fuel directly into them associated combustion chambers 20a to 2Od. The operation of the internal combustion engine 10 is controlled or regulated by a control and regulating device 22 which, among other things, also controls the injection valves 18a to 18d.

FIGS. 2a to 2c schematically show the injection valve 18a according to FIG. 1 in a total of three different operating states. The further injection valves 18b, 18c, 18d illustrated in FIG. 1 have a corresponding structure and functionality.

The injection valve 18a has an electromagnetic actuator which has a magnetic coil 26 and a magnetic armature 30 cooperating with the magnetic coil 26. The magnet armature 30 is connected to a valve needle 28 of the injection valve 18 a, that it relative to the valve needle 28 is movable relative to a direction of movement of the valve needle 28 in Figure 2a with a non-disappearing mechanical clearance. This results in a two-part mass system 28, 30, which causes the drive of the valve needle 28 by the electromagnetic actuator 26, 30. By this two-part configuration, the mountability of the injection valve 18 a is improved and an undesirable bouncing of the valve needle 28 in the

Impact in their valve seat 38 is reduced.

In the presently illustrated in Figure 2a configuration, the axial play of the armature 30 is limited to the valve needle 28 by two stops 32 and 34. However, at least the lower stop 34 in FIG. 2a could also be realized by a region of the housing of the injection valve 18a.

The valve needle 28 is acted upon by a valve spring 36 as shown in Figure 2a with a corresponding spring force against the valve seat 38 in the region of the housing 40. In Figure 2a, the injection valve 18a is shown in its open state. In this open state, the armature 30 is moved by energizing the solenoid 26 in Figure 2a upwards, so that it moves out of its valve seat 38 against the spring force by engaging in the stop 32, the valve needle 28. As a result, fuel 42 can be injected from the injection valve 18a into the combustion chamber 20a (FIG. 1).

As soon as the energization of the magnetic coil 26 is terminated by the control unit 22 (FIG. 1), the valve needle 28 moves toward its valve seat 38 under the action of the spring force exerted by the valve spring 36 and carries the magnet armature 30 with it. A power transmission from the valve needle 28 to the

Magnetic armature 30 takes place here again by the upper stop 32nd

As soon as the valve needle 28 ends its closing movement with the impact on the valve seat 38, the magnet armature 30, as shown in FIG. 2b, can move downwardly due to the axial play in FIG. 2b until it, as in FIG

Figure 2c is illustrated, is applied to the second stop 34.

According to the invention, the method described below with reference to the flowchart according to FIG. 3 is carried out in order to obtain information about an operating state of the injection valve 18a. In a first step 100 of the method according to the invention, at least one electrical operating variable of the electromagnetic actuator 26, 30 is detected. This may be, for example, an actuator voltage applied to the magnetic coil 26 or else an actuator current flowing through the magnetic coil 26.

According to the invention, a variable characterizing the acceleration of a movable component of the electromagnetic actuator 26, 30, in particular of the magnet armature 30 of the electromagnetic actuator, is formed as a function of the at least one electrical operating variable of the electromagnetic actuator 26, 30, which takes place in step 1.

Depending on the variable characterizing the acceleration, an operating state of the injection valve 18a is finally closed in step 120.

In particular, the operating method according to the invention can be used to determine an actual hydraulic closing time at which the valve needle 28 (FIG. 2 a) encounters its valve seat 38.

In a first preferred embodiment of the operating method according to the invention is used as an electrical operating variable of the electromagnetic actuator applied to the solenoid 26 actuator voltage u, and as the acceleration of the armature 30 characterizing size, the first time derivative ιl the actuator voltage u is formed and used.

Figure 4 shows an example of a simplified time course of a needle stroke h of the valve needle 28 (Figure 2a) and a corresponding section of the time course of the first time derivative ύ the actuator voltage u.

At the time tθ, the valve needle 28 is lifted out of its rest position marked by the Nadelhubwert hθ on the valve seat 38, which is accomplished by the solenoid 26 is energized accordingly and the armature 30 is moved upward in Figure 2a, wherein it under power transmission via the stop 32, the valve needle 28 entrains. At the time t1, the valve needle 28 has reached its maximum needle stroke, and the energization of the solenoid 26 is terminated by the control unit 22 (Figure 1). As a result, no magnetic force acts from the solenoid 26 to the armature 30, so that the mass of the valve needle 28 and the armature 30 having mass system under the action of the spring force of the valve spring 36 is moved in Figure 2a down. Figure 4 shows for t> t1 accordingly a decreasing needle stroke h. When the needle stroke h begins to decrease as of time t1, there is an essentially exponential decay of the first time derivative ύ of the actuator voltage u at the magnet coil 26.

According to the invention, it has been recognized that the first time derivative .alpha. Of the actuator voltage u when the valve needle strikes its valve seat 38 has a local minimum Mu, which represents a clearly discernible deviation from the otherwise exponentially decaying time profile of the first derivative ά.

According to investigations by the Applicant, this local minimum Mu results from the fact that, when the valve needle 28 strikes its valve seat 38, the armature 30 loosens from the valve needle 28 by virtue of the non-vanishing mechanical backlash and initially continues in the closing direction, that is to say in FIG. 2b down, moving forward, before he hits the stop 34.

This means that from the time t = t2, the spring force exerted by the valve spring 36 no longer acts on the magnet armature 30 via the stop 32, resulting in a change in the acceleration of the magnet armature 30 evaluated according to the invention.

As already described above, the change in the acceleration of the magnet armature 30 occurring at the time t2 results in one

Minimum Mu of the first time derivative. the actuator voltage u.

Accordingly, by evaluating the first time derivation ü by the control unit 22 (FIG. 1), the actual hydraulic closing time t2 of the injection valve 18a (FIG. 2a) can be ascertained. A particularly precise detection of the local minimum Mu is possible if in the time range of interest around the closing time t2 an actuator current flowing through the magnetic coil 26 is impressed to a predeterminable value, preferably a constant value, in particular zero.

The time derivative ύ of the actuator voltage u can be subjected to filtering for interference suppression and thus more efficient signal processing before the evaluation, it being advantageous to carry out the differentiation of the actuator voltage u and the filtering of the derived signal in one step, e.g. by filtering the voltage signal u by means of a

High-pass filter.

As an alternative to the embodiment described above, according to the invention, the variable characterizing the acceleration of the magnet armature 30 may also depend on the current flowing through the magnet coil 26

Aktorstroms i are formed. In this case, the magnitude that characterizes the acceleration of the magnet armature 30 is the first time derivative l of the actuator current i.

Figure 5 shows a time course of the Nadelhubs h, as he already under

Referring to Figure 4 has been described. In addition to the Nadelhubverlauf h is for the time t2, at which the valve needle 28 strikes in its closing movement on the valve seat 38 (Figure 2a), the stroke course hA of the armature 30 shown in dashed lines to illustrate that the armature 30 after the time t2 first in the closing direction, that is in

Figure 2b down, further moved, before he hits the stop 34.

The impact of the armature 30 on the stop 34 takes place according to Figure 5 at the time t3.

FIG. 5 also shows schematically a section of the time profile of the first time derivative J of the actuator current i considered according to the invention.

As can be seen in FIG. 5, in the present case the acceleration of the

Magnetankers 30 characterizing size used first time derivative i of the actuator current i a local maximum Mi or a kink at the time t2, to which the valve needle 28 impinges on the valve seat 38. Therefore, according to the invention, the local maximum Mi or the bend at the time t2 can be analyzed and used as a criterion for the actual hydraulic closing of the injection valve 18a.

A particularly precise evaluation of the first time derivative t of the actuator current i is in turn possible when the actuator voltage u applied to the magnet coil 26 of the electromagnetic actuator 26, 30 is impressed on a presettable value, in particular zero.

The time derivative i of the actuator current i can be subjected to filtering for interference suppression and thus more efficient signal processing before the evaluation, it being advantageous to carry out the differentiation of the actuator current i and the filtering of the derived signal in one step, e.g. by filtering the current signal i by means of a

High-pass filter.

In a further very advantageous embodiment of the method according to the invention, a first electrical operating variable of the electromagnetic actuator 26, 30 is detected and fed to an observer member which simulates the electromagnetic actuator 26, 30 without consideration of the retroactivity of an armature movement to electrical operating variables of the electromagnetic actuator, wherein the observer member an observed second electrical operating variable of the electromagnetic actuator determined. The observed second electrical operating variable is compared according to the invention with a detected second electrical operating variable and the acceleration characterizing variable is determined as a function of the comparison result.

FIG. 6 shows a simplified equivalent circuit diagram of the magnetic actuator 26, 30

(Figure 2a), wherein the reference numeral 46 denotes a main current path and the reference numeral 48, an eddy current path. The resistor R _{5 in} this case represents a series resistance of the magnetic coil 26 (FIG. ₂ a). The inductive elements L _h , L ₀ represent the respective inductance of the main current path 46 and the eddy current path 48. The resistance R _w * represents an ohmic resistance of the eddy current path 48. The current i _m flows through the main current path, while the current i _w * flows through the eddy current path 48. The currents i _m , i _w * together form the drive current i, with which the electromagnetic actuator 26, 30 is acted upon by the control unit 22. At the terminals of the electromagnetic

Actuator 26, 30 is as already described, the actuator voltage u.

FIG. 7 shows a block diagram which realizes the function of the equivalent circuit diagram described above with reference to FIG.

The eddy current path 48 is represented in the block diagram in accordance with FIG. 7 by an integrator with the time constant T _σ and an associated proportional element with the gain K _Rw .

The main current path 46 is represented in the block diagram according to FIG. 7 by the integrator with the time constant T _{h (} not further described ₎ and a proportional element with the gain K _Rs assigned to this integrator.

Figure 8 shows a structure of the observer member 56 according to the invention, the input side, as already described, the actuator voltage u is supplied, and outputs at its output an observed actuator current ib. By means of the adder 58, a comparison is made between the observed actuator current ib and the actual measured actuator current i, for example, measured, which leads to the comparison result .DELTA.ib. As can be seen in FIG. 8, the comparison result Δib is supplied to the feedback element 60, which forms an output _quantity u _{kOrr therefrom} , which is subtracted via the adder 62 from the detected actuator voltage u.

The feedback element 60 may be formed, for example, as a proportional element, as a proportional-integral element or as a feedback element of higher order and / or more complex structure.

By subtracting the output _quantity u _kOrr , the current ib observed by the observer _{element 56} is _tracked to the current i measured by measurement. Since the difference between the real electromagnetic actuator 26, 30 and the replica shown in Figure 8 a corresponding control path in the observer member 56 in a lack of reaction of the armature movement, the output quantity U _corr exact this reaction, this reaction has a proportionality to the speed of the armature 30. At the time of closing the injection valve 18a (FIG. 2a), as already described, there is no abrupt change in the speed of the magnet armature 30, but only the valve needle 28.

At the time of valve closure, however, there is a relatively large change in the first derivative of the output _{u.sub.rr.sub.rr.}

According to investigations by the Applicant, the gradient of the output _quantity U _corr to the closing time _{t 2} (FIG. 4) is usually subjected to a sign change, which leads to an extremum in the temporal course of the output _quantity u _kOrr . This extremum is inventively detected and used as a signal for the closing time t2 of the injection valve 18a.

By a corresponding parameterization of the feedback element 60 (FIG. 8), the transmission behavior between the velocity of the

Magnetic armature 30 and the output u _{kOrr be} influenced. In particular, a filtering of interference signals can thereby be carried out, resulting in an even more precise evaluation.

The method described with reference to FIGS. 6, 7, 8 advantageously operates independently of an actual actuator current i, an actuator voltage u or an impression of one or both of these variables and, in particular, also independent of an optionally existing operative connection between the two variables u, i.

Instead of the output u _{kOrr of} the feedback _element 60, an internal size of the feedback _element 60 can be used to detect the closing time t2 (FIG. 4). If the feedback element 60 is designed, for example, as a proportional-integral element, instead of the output _quantity U _corr, for example, only the integral component of the feedback quantity can be used. If less stringent requirements are placed on the significance of the output signal U _korr with regard to the closing time t 2, the scatter path 48 of the equivalent circuit diagram depicted in FIG. 6 can also be neglected, resulting in a simpler evaluation.

According to the invention, it is also possible to take into account a plurality of different eddy current paths each having a different commutation inductance to the magnet coil 26. For this purpose, in the block diagram according to FIG. 7, in addition to the main current path 48, further current paths can be connected in parallel, each of which can have different integrator and feedback element parameters.

In addition, it is also possible to have non-linear relationships between the variables under consideration in the observer member 56 used according to the invention

(Figure 8), whereby saturation and hysteresis effects of a real magnetic circuits or electromagnetic actuator 26, 30 can be taken into account.

In addition to the application of the operating method according to the invention for

Closing time detection in such injectors 18a, which have a complex mass system 28, 30 for valve actuation, the inventive method is also suitable for closing time detection in conventional injectors with a rigid coupling between the electromagnetic actuator and the valve needle.

The observer member 56 described with reference to FIG. 8 can be embodied both digitally and analogously and is preferably implemented in a computing unit of the controller 22 (FIG. 1).

In addition to the precise detection of the closing time t2 (FIG. 4), the operating method according to the invention also makes it possible to detect other operating states or state transitions of the injection valve 18a (FIG. 2a), which are accompanied by a correspondingly characteristic change in the acceleration of the armature 30. As an alternative or in addition to the above-described consideration of local extrema of the variables characterizing the acceleration, it is also possible to compare a time profile of the variables characterizing the acceleration with a predetermined reference curve or also other features, such as a bend over time or the like, to identify.

Particularly preferably, the information obtained according to the invention is used to control an operation of the injection valves 18a,... 18d.

Claims

claims

1 . Method for operating an injection valve (18a), in particular an internal combustion engine (10) of a motor vehicle, in which a component of the injection valve (18a), in particular a valve needle (28), is driven by means of an electromagnetic actuator (26, 30), characterized in that as a function of at least one electrical operating variable of the electromagnetic actuator (26, 30) a variable characterizing the acceleration of a movable component of the electromagnetic actuator, in particular of a magnet armature (30) of the electromagnetic actuator, is formed, and in dependence on the variable characterizing the acceleration an operating state of the injection valve (18a) is closed.

2. The method according to claim 1, characterized in that the valve needle (28), preferably spring-loaded in a closing direction of the valve needle, that the magnet armature (30) is connected to the valve needle (28), that the armature (30) related a movement direction of the valve needle (28) is movable with a non-disappearing mechanical play relative to the valve needle (28), and that from a characteristic feature of the acceleration of the

Magnetankers (30) characterizing size is closed, that the armature (30) from the valve needle (28) dissolves.

3. The method according to any one of the preceding claims, characterized in that as an electrical operating variable of the electromagnetic actuator (26, 30) to a solenoid coil (26) of the electromagnetic actuator (26, 30) applied actuator voltage (u) is used, and that as the acceleration of the magnet armature (30) characterizing size, the first time derivative (ύ) of the actuator voltage (u) is formed.

4. The method according to claim 3, characterized in that it is concluded from the occurrence of a local minimum (Mu) of the first time derivative (ύ) of the actuator voltage (u) that the magnet armature

(30) from the valve needle (28) triggers.

5. The method according to any one of claims 3 to 4, characterized in that by the magnetic coil (26) flowing actuator current (i) to a predetermined value, in particular zero, is impressed.

6. The method according to any one of the preceding claims, characterized in that as electrical operating variable of the electromagnetic actuator (26, 30) by a magnetic coil (26) of the electromagnetic actuator (26, 30) flowing Aktorstrom (i) is used, and that as the acceleration of the armature (30) characterizing magnitude of the first time derivative (i) of the actuator current (i) is formed.

7. The method according to claim 6, characterized in that it is concluded from the occurrence of a local maximum (Mi) of the first time derivative (J) of the actuator current (i) that the armature (30) from the valve needle (28) dissolves ,

8. The method according to any one of claims 6 to 7, characterized in that one of the solenoid coil (26) of the electromagnetic actuator (26, 30) voltage applied actuator voltage (u) to a predetermined value, in particular

Zero, is imprinted.

9. The method according to any one of the preceding claims, characterized in that a first electrical operating variable (u) of the electromagnetic actuator (26, 30) detected and an observer member (56) is supplied to the electromagnetic actuator (26, 30) without taking the Reaction of an armature movement to electrical operating variables (u, i) of the electromagnetic actuator (26, 30) simulates, wherein the observer member (56) an observed second electrical operating variable (ib) of the electromagnetic actuator (26, 30) determines that the observed second electrical Operation size (ib) with a detected second electrical operating variable (i) is compared, and that the Acceleration characterizing variable (ukorr) is determined as a function of the comparison result (Δib).

10. The method according to any one of claims 3 to 9, characterized in that the first time derivative (ύ) of the actuator voltage (u) and / or the first time derivative (i) of the actuator current (i), in particular before a further evaluation, a Filtering is subjected by a filter element, wherein a formation of the first time derivative (ύ, ι) and the filtering preferably carried out in one step, for example by means of a high-pass filtering.

1 1. Computer program, characterized in that it is programmed for use in a method according to one of the preceding claims.

12. Electronic or optical storage medium for a control and / or

Control device (22) of an internal combustion engine (10), characterized in that a computer program for use in a method of claims 1 to 10 is stored on it.

13. Control and / or regulating device (22) for an internal combustion engine (10), characterized in that it is designed for use in a method according to one of claims 1 to 10.