DE10331057A1 - Piezoelectric actuator idling stroke adjustment procedure especially for operating high pressure fuel injection valve of combustion engine, requires comparing idling stroke value with minimal or maximum tolerance value allowed - Google Patents

Abstract

A method for driving a piezoelectric actuator involves initially determining at least one parameter which is directly or indirectly dependent on the idling stroke (d) of the piezoelectric actuator (P)., followed by comparing the ascertained value for the idling stroke with a minimal and/or maximal permissible tolerance value (dmin, dmax), and then charging the piezoelectric actuator with a specified charge (Q), so that the idling stroke of the actuator (P1,P2) at the start of the actual drive corresponds to a specified idling stroke (d soll) so that the piezoelectric actuator, for a given time (t), is charged with a current (IE) with a given current intensity. An independent claim is included for a device for adjusting the idling stroke of a piezoelectric actuator.

Description

The The invention relates to a method and a device for driving a piezoelectric actuator, in particular a piezoelectric Actuator for operating a high-pressure injection valve of an internal combustion engine.

piezoelectric Change elements when applying a voltage quickly their length. Around larger changes in length To achieve piezoelectric actuators stack a variety arranged piezoelectric elements. The length and the change in length The piezoelectric actuator is inter alia of a piezoelectric Actuator voltage applied. However, there are also other parameters, such as the ambient temperature, acting on the piezoelectric actuator external force, aging phenomena or depolarization, influence on the change in length of the actuator.

Becomes Such an actuator, for example, to control a high-pressure injection valve used in an internal combustion engine, so is a precise and reproducible control of the piezoelectric actuator due the small injection quantities of great importance. Here depends on Fuel pressure exerted a force on the piezoelectric actuator, the in turn affect the length of the actor.

Here is due to the pressurized liquid to be injected exerted a force on the actor, as already mentioned Influence on the change in length of the actor.

In 4 is a high-pressure injection valve of an internal combustion engine shown schematically, which is driven by a piezoelectric actuator P. The working chamber of the high pressure injection valve is not shown here. The piezoelectric actuator P has two terminals A and is surrounded by a housing G.

If a positive voltage is applied to the terminals A of the piezoelectric actuator P, then the actuator P is extended in the direction of preferential polarization of the piezoelectric ceramic (see arrow VR in FIG 4 ). The high-pressure injection valve has a gap d, the so-called idle stroke, which serves as a safety margin for changes in length of the piezoelectric actuator P. This idle stroke d typically has a dimension between 3 and 5 microns. The illustrated high-pressure valve has a low-pressure region L and a high-pressure region H, which are separated by a membrane M.

Changes while the operation of the piezoelectric actuator of this Leerhub d, so also changes the injected by activation of the actuator P amount of liquid. This amount of fluid can be from the opening time of the valve and the fluid pressure calculate at high pressure. At a reduced idle stroke d lengthens The opening hours of the valve, since the piezoelectric actuator P earlier than the Sollleerhub impinges on the valve seat V. This will increase the amount of fluid injected increased.

From the patent DE 199 05 340 C2 a method and an arrangement for presetting and dynamic tracking piezoelectric actuators is known. Here, the pulsed drive voltage is superimposed on a DC voltage signal. This DC signal causes a change in length of the piezoelectric actuator. In this way, temperature-related changes in length can be compensated.

There however, superimposed on the DC voltage signal of the pulsed drive voltage There may be inaccuracies in the amount of fluid injected come.

By an increase the force acting on the piezoelectric actuator occurs an enlargement of the Idle stroke. This power increase will in common rail systems mainly by the increase in pressure in the fuel tank (rail) and in pump-nozzle systems mainly triggered by pressure oscillations in the fuel supply and return.

The The object of the invention is a method and a device for adjusting an idle stroke of a piezoelectric actuator create any changes the Leerhubs already compensated before the actual charging of the actuator become.

These The object is achieved by a Method with the in claim 1 and by an arrangement with solved specified in claim 8 features.

The method according to the invention and the device according to the invention achieve the object by determining a deviation of the idle stroke from a nominal idle stroke before the actual injection. Subsequently, the piezoelectric actuator is driven with a constant current for a time dependent on the deviation of the actual idle stroke from the desired idle stroke time. The idle stroke now corresponds to the nominal idle stroke and the piezoelectric actuator is only now according to the ge Wanted deflection controlled. The deflection of the piezoelectric actuator is thus carried out with a low tolerance and high reproducibility.

preferred embodiments The invention are set forth in the subclaims.

Preferably the idle stroke is based on the temperature of the piezoelectric actuator and / or determines the force acting on the piezoelectric actuator force.

Becomes the piezoelectric actuator, for example, to control an injector used, so can the pressure of a liquid to be injected or a funding rate Information about give the current idle stroke.

In a further preferred embodiment is the piezoelectric actuator for driving a control valve for one Injection system of an internal combustion engine used, here can additionally the Speed of the internal combustion engine influences the control of the idle stroke to have.

These aforementioned parameters can in a simple way without additional Sensors are detected and thus allow easy Setting a precise Idle stroke.

Become several piezoelectric actuators are used in a similar environment, Thus, the Leerhubeinstellung due to the one or more Actuators determined parameter for all actuators are the same. So can be a quick and easy Leerhubeinstellung be made with multiple actuators.

One embodiment the method according to the invention and the device will be described below with reference to the schematic drawings explained in more detail. It demonstrate:

1 a block diagram of an embodiment of a device according to the invention,

2 a schematic representation of a current sink for the device according to 1 .

3 a flowchart showing the steps of an embodiment of a method according to the invention, and

4 a known high-pressure injection valve of an internal combustion engine having a piezoelectric actuator.

1 shows an embodiment of a circuit arrangement for driving piezoelectric actuators P. In the illustrated embodiment, two piezoelectric actuators P1 and P2 are shown. The actuators have a negative (-) and a positive voltage connection (+). The negative terminal (-) of the actuators P1, P2 is in each case connected via a selection switch S31 or S32 to ground (GND). The positive terminal (+) of the piezoelectric actuators P1 and P2 is connected via a series resonant circuit SK and a first switch S1 to a voltage source U1 and a drive unit AE. This voltage source U1 is here a vehicle battery of a motor vehicle and has a nominal voltage of 12 volts.

Of the positive connection (+) of the actuators P1 and P2 is also above the Series resonant circuit and a second switch S2 with the drive unit AE electrically connected. This drive unit AE is also powered by the voltage source U1. The drive unit AE is still connected to mass.

Furthermore, the device has a current sink arranged parallel to the selection switches S31 and S32 11 with a control input st, which is connected on the one hand to the negative terminals (-) of the actuators P1 and P2 and the other to ground.

A control unit ST provides the control signal for controlling the control input st of the current sink and / or the switch S1 as a function of a plurality of parameters. For generating the control signal, the control unit ST on several inputs, here a temperature signal input T, a speed signal input n and a pressure signal input p _rail whose input signals are used to generate the control signal st.

The temperature T can be the temperature of one or more piezoelectric actuators P1, P2 or a temperature or a parameter which provide information about the temperature of the piezoelectric actuators P1, P2, for example the fuel temperature or the capacity of the actuator P. The pressure value p _Rail can be supplied by a pressure sensor, as it already exists, for example, in the high-pressure reservoir (rail) of the internal combustion engine. Here, a pressure signal that is recorded by the piezoelectric actuator itself can be used.

2 shows an embodiment of a current sink (constant current source) 11 , The negative terminals of the piezoelectric actuators P1, P2 are connected via a respective diode D1 or D2 to the collector of a transistor T1. In this case, the diodes D1, D2 are arranged such that their forward direction points in the direction of the collector of the transistor T1.

The Base of the transistor T1 is over a resistor R1 connected to the control input st. The emitter of the transistor t1 is over an emitter resistor R2 connected to ground.

The current flowing through the emitter resistor R2 current I _E is, as far as the current sink is considered to be ideal, regardless of the voltage applied to the current sink - here at the base of the transistor T1.

It can Here, however, other constant current sources are used.

According to the in 3 illustrated flowchart is after the start of the method according to the invention (step 301 ) in step 302 the idle stroke d determined. For this purpose, the parameters T, speed n and / or pressure p _{Rail are} recorded by the control unit ST and, depending on these parameters, the current idle stroke d is determined. In the following step 303 it is checked whether the current idle stroke d is within a tolerance range between a minimum allowable idle stroke d _min and a maximum allowable idle stroke d _max . If this is the case, go directly to step 305 branched and the actuator P loaded from the drive unit AE via the then closed switch S2 and the series resonant circuit SK.

Otherwise, in step 304 the idle stroke d at a predetermined Sollleerhub d _ref, the set in the tolerance range between d _n and _mi is d _max. For this purpose, the switch S1 is closed and applied via the series resonant circuit SK of the actuator P with the voltage of the voltage source U1. In this case, the current I _{R2 flows} as long as the control signal of the control unit ST is applied to the control input st and so the transistor T1 is turned on. In this way, the amount of charge applied to the one or more piezoelectric actuators P1, P2 can be applied in accordance with the difference between the actual idle stroke d and the _target idle stroke d _desired .

The Switches S1 and S2 are here by a control unit, not shown driven.

In the exemplary embodiment illustrated here, the piezoelectric actuators P1 and P2 are charged with the same electrical charges. However, if it should be necessary to make a Leerhubeinstellung for each actuator P1, P2 separately, this is, for example, simply by installing further switching elements in the connection between the nega tive connection of the actuators P1, P2 and the current sink 11 possible.

In the next step (step 305 ), the actuator P1 or P2 selected by closing one of the selector switches S31 or S32 is then charged by the drive unit AE via the then closed switch S2.

If the actuator P1, P2 used to control an injection valve of an internal combustion engine, it is now ensured that only a small tolerance and a very high reproducibility of the injection quantity can be achieved when opening the valve. In the following step 306 The actuator is also discharged via the drive unit AE and the closed switch S2 again and in step 307 the idle stroke adjustment ends.

In a subsequent further control process, the process begins again at step 301 ,

The diodes D1 and D2 in the current sink 11 serve here for decoupling of the individual piezoelectric actuators P during the actual charging phase (step 306 ).

As the current through the current sink 11 kept constant, the charge Q applied to an actuator P1, P2 can simply be determined by the time that the switch S1 is closed and the current sink is driven by the control signal applied to the control input.

Claims (9)

A method for driving a piezoelectric actuator, comprising the following steps: - determining at least one parameter which is directly or indirectly dependent on the idle stroke (d) of the piezoelectric actuator (P), - comparing the determined value for the idle stroke (d) with a minimum and / or maximum permissible tolerance value (d _min , d _max ), and - charging the piezoelectric actuator with a predetermined charge Q, so that the idle stroke (d) of the piezoelectric actuator (P1, P2) at the beginning of the actual control a predetermined idle stroke (d _soll ) corresponds, wherein the piezoelectric actuator for a predetermined time (t) with a current (I _E ) is charged with a predetermined current. Method according to claim 1, characterized in that the charging time (t) depends on the temperature (T) of the piezoelectric actuator (P1, P2) determined becomes. Method according to one of claims 1 or 2, characterized in that the charge (Q) is loaded with the piezoelectric actuator (P1, P2) is determined as a function of a force acting on the piezoelectric actuator force. Method according to one of claims 1 to 3, characterized in that the piezoelectric actuator (P) is used for driving an injection valve and the charge (Q) for adjusting the idle stroke as a function of a pressure (p _rail ) and / or a delivery rate is determined , Method according to one of claims 1 to 4, characterized that the piezoelectric actuator (P1, P2) for driving an injection valve of a Internal combustion engine is used and for determining the charge (Q) with which the piezoelectric actuator (P1, P2) is charged, the speed (n) the internal combustion engine is used. Method according to one of claims 1 to 6, characterized that after setting the idle stroke (d) the charging by a powered by the voltage source (U1) drive device by closing a selector switch (S31 or S32) and a charging switch (S2) carried out becomes. Method according to one of claims 1 to 7, characterized that several piezoelectric actuators (P1, P2) with the same electric charge (Q) are charged to set the idle stroke (d). Device for adjusting an idle stroke of a piezoelectric actuator, comprising: - a voltage source (U1) and a drive unit (AE) which is supplied with energy by the voltage source (U1), - a first switch (S1) connected between the voltage source (U1) U1) and a piezoelectric actuator (P1, P2) upstream of the series resonant circuit (SK) is arranged, - a second switch (S2), which is arranged between the drive unit (AE) and the series resonant circuit (SK), - a selection switch (S31) which is connected, on the one hand, to the connection (-) of the piezoelectric actuator (P1, P2) facing away from the series resonant circuit (SK) and, on the other hand, to ground (GND), and - a current sink ( 11 ) arranged in parallel with the selection switch (s31, s32). Apparatus according to claim 8, characterized in that the current sink ( 11 ) has a transistor (T1) whose base is connected to a control input (st), wherein the control input (st) together with the switch (S1) is driven, whereby the piezoelectric actuator (P1, P2) for a predetermined time (t ) is charged with a constant current (I _R2 ).