DE10120143A1 - Capacitive setting element control method for fuel injection valve of IC engine, involves charging and discharging of capacitive setting element via inductive element and charging or discharging switch - Google Patents

Abstract

The control method has a charging switch (SW1) operated in repetition during a charging process, for charging at least one capacitive setting element (P1,P2,..Pn) via an inductive element (L), with a discharging switch (SW2) operated in repetition during a discharging process, for discharging the capacitive setting element via the inductive component. The charge is transferred from an to a storage capacitor (C0) which is charged from a supply voltage (U0) via the inductive element and the discharging switch, when the capacitive setting element is inactive. An Independent claim for a circuit for control of a capacitive setting element is also included.

Description

The invention relates to a method for controlling at least one capacitive Actuator according to the preamble of claim 1 and a circuit order to carry out the procedure.

A method according to the preamble of claim 1 is, for example, from known from DE 197 33 560 A1. In this method, a capacitive actuator is used by repeatedly pressing a charge switch or a discharge switch an inductive component is charged or discharged, during charging Charge taken from a storage capacitor and via the inductive construction element is supplied to the actuator and during the unloading process La dung removed from the control element and partially over the storage capacitor the inductive component is supplied. The storage capacitor is in front Start of charging from a DC voltage source via a DC voltage voltage-to-DC converter to an operation required for operation voltage loaded. A disadvantage here is the high circuit complexity and space requirements of the circuitry required to carry out the method order.

The invention is therefore based on the object of a method according to the Oberbe handle of claim 1 specify that in a simple manner with a small scarf tion and cost is feasible. The invention is also the object based on specifying a circuit arrangement for performing the method.  

The object is achieved by the features of claim 1 and by the Merk male of claim 6 solved. Advantageous refinements and training conditions result from the subclaims.

According to the invention, a capacitive actuator or one of several capacitive actuators during a charging process by repeated actuation a charging switch charged via an inductive component or during a Unloading process by repeatedly pressing a discharge switch via the same Discharge che inductive component, with charging from a Storage capacitor is removed and the charge is discharged during the discharge process Cherkondensator is supplied and wherein the storage capacitor via the in ductive component, preferably in repeating time intervals, to a Operating voltage is charged by deactivating the actuator or deactivating th actuators a DC supply voltage to a connection of the indukti Vern component is created and the discharge switch is operated repeatedly.

So it is no longer necessary to have a complex and costly match voltage-to-voltage converter for charging the storage capacitor see.

The actuator or each of the actuators is advantageously deactivated by it is de-energized, d. H. by an actuator to be deactivated leading current path is interrupted. Preferably an actuator or each the actuators only after the loading or unloading process has ended, through which it is loaded or unloaded, released for deactivation. In the The use of several actuators is preferably not more of the actuators which is activated at the same time, so that the actuators at different time intervals be loaded or unloaded.

The method can be carried out with a simple circuit arrangement. A such circuit arrangement comprises an output terminal to which the Stell link or the actuators is or are connected via the inductive Component is connected to a circuit node, which in turn via the charging switch and a first diode connected in parallel with the memory capacitor is connected and via the discharge switch and a parallel to it switched second diode with a preferably at a reference potential  the power supply connection is connected. The actuator or any of the Actuators are their own selection switches for activation or deactivation assigned to the respective actuator, the actuator or each of the actuators which in its own the output connection with the power supply finally connecting current branch to the selection switch assigned to it is connected in series. A connectable is preferably connected to the output connection re DC voltage source connected to the in the connected state DC supply voltage is applied to the output connection.

In an advantageous embodiment of the circuit arrangement, the actuator or each of the actuators is designed as a piezoelectric element.

An embodiment of the invention is described below with reference to the figure wrote.

The figure shows a circuit arrangement for controlling a plurality of actuators P1, P2,. , , Pn.

With the actuators P1, P2,. , , Pn are used in an internal combustion engine with power direct injection of fuel actuated. The actuators P1, P2,. , , Pn are executed as piezoelectric elements and thus have the property to expand depending on the change in their electrical charge or contract. The result of a charging or discharging process Change in length of an actuator is used to close an actuator move, whereby the injector operated by this actuator by value that is dependent on the change in charge is opened or closed further.

According to the figure, the circuit arrangement has between an output connection N0 and a voltage supply connection N1 which is at ground potential a plurality of parallel current branches, one in each of the current branches Actuators P1, P2,. , , Pn to a respective actuator P1 or P2 or. , , pn assigned selection switch S1 or S2 or. , , Sn is connected in series. Zwi is the output terminal N0 and the voltage supply terminal N1 a switchable DC voltage source V is also connected. This switchable DC voltage source V is connected in series from a supply switch SW0 and one intended to generate a DC supply voltage U0  DC voltage source V0, for example a vehicle battery. The Output terminal N0 is also via an inductive structure designed as a coil L. element connected to a circuit node N3, which in turn via a Charging switch SW1 and a first diode D1 connected in parallel with it Most connection of a storage capacitor C0 is connected and via an Ent charging switch SW2 and a second diode D2 connected in parallel with one on the second connection of the voltage supply connection N1 Storage capacitor C0 is connected. The diodes D1, D2 are in the swinging state with open switches SW0, SW1, SW2, S1, S2,. , , Sn and charged storage capacitor C0 polarized in the reverse direction. The circuit arrangement voltage also includes a control unit, not shown in the figure, for controlling the Switches SW0, SW1, SW2, S1, S2,. , , Sn.

When the circuit arrangement is started up, the storage capacitor C0 first on one for the control of the actuators P1, P2,. , , Pn required loading drive voltage UC charged, for example to a voltage value of approx. 100 V. For this purpose, the selection switches S1, S2,. , , Sn in the actuator branches the P1, P2,. , , Pn opened and the actuators S1, S2,. , , Sn thus deactivated. at deactivated actuators P1, P2,. , , Pn then becomes the supply switch SW0 closed and thus the supply voltage U0 to the output finally N0 created. Then the discharge switch SW2 is open when the charge switch SW1 is pressed repeatedly until the desired operating voltage UC on the memory Cher capacitor C0 is present. Then the supply switch SW0 is like the opened. During the charging of the storage capacitor C0, the part of the Circuit arrangement, the coil L, the first diode D1, the discharge switch SW2 and the storage capacitor C0 comprises, as a step-up converter, the between the Output terminal N0 and the voltage supply terminal N1 DC supply voltage U0 to the drop across the storage capacitor C0 driving voltage UC increases.

The corresponding actuator P1 or P2 is used to actuate an injection valve respectively. . , , Pn with supply switch SW0 open, d. H. at from the actuators P1, P2,. , , Pn decoupled DC voltage source V0, charged and discharged. An actuator supply process can also the multiple loading and unloading each position limbs include.  

The actuator to be loaded or unloaded P1 or P2 or. , , Pn, if it is not already activated by closing the selection switch assigned to it S1 or S2 or. , , Sn is activated and the remaining selection switches are, if they are not already open, open to deactivate the other actuators. To the Loading the activated actuator P1 or P2 or. , , Pn then becomes the charging switch SW1 repeatedly pressed with the discharge switch SW2 open. Accordingly, the Discharge switch SW2 repeatedly pressed with the charging switch SW1 open in order to activated actuator P1 or P2 or. , , Discharge Pn. Due to the polarity of the Diodes D1, D2 is the first diode D1 when charging and the second diode D2 when discharging that of the activated actuator P1 or P2 or. , , Pn always locked.

The part of the circuit arrangement that acts on the storage capacitor C0, the charge switch SW1, the second diode D2, the coil L and the activated actuator P1 or P2 or. , , Pn includes, when loading, i.e. H. when loading the activated Actuator, as a buck converter, with which the applied to the storage capacitor C0 Operating voltage UC converted into a voltage applied to the activated actuator is set. This voltage applied to the activated actuator is less than that operating voltage UC present at the storage capacitor C0. Works accordingly the part of the circuit arrangement that the storage capacitor C0, the discharge switch SW2, the first diode D1, the coil L and the activated actuator P1 or P2 or. , , Pn includes, in the unloading process, i.e. H. when unloading the activated Actuator, as a step-up converter, with which the applied to the activated actuator Voltage into the higher operating voltage UC compared to this voltage is set.

The activated actuator P1 or P2 or. , , Pn will flow to him through one or current flowing out of it, which is led over the coil L, loaded or unloaded. The coil L acts as an energy store, the electri energy from the storage capacitor C0 (during charging) or from the activated th actuator P1 or P2. respectively. . , , Pn (during the discharge process) is supplied. This Energy is stored in the coil L as magnetic energy and after one Actuation of the charge switch SW1 (during the charging process) or the discharge switch SW2 (during the unloading process) to the activated actuator or to the storage con capacitor C0 given off as electrical energy. The times and the duration of the Energy storage and energy delivery are actuated by the switches gene determined. The actuating current I can thus be varied by varying the duration of the switching  times and the switching breaks of the charge and discharge switch SW1 or SW2 control ern, this control advantageously being carried out by regulation in such a way that the length of the activated actuator P1 or P2 or. , , Pn yourself accordingly changes a desired time course.

Due to the energy transfer from the storage capacitor C0 via the coil L to the activated actuator P1, or P2, or. , , Pn and from the activated actuator P1, or P2, or. , , Pn via coil L back to storage capacitor C0 is selected During the charging process, charge is removed from storage capacitor C0 and selected rend the discharge process charge the storage capacitor C0 again leads. However, due to ohmic losses, not all of it Storage capacitor C0 charge removed during charging of the subsequent unloading process. This loss of charge can, however, be compensated for by the actuators P1, P2,. , , Pn in time interval len in which none of the actuators P1, P2,. , , Pn can be loaded or unloaded should, d. H. after completion of a loading or unloading process and before the start of the next charge or discharge, if they are not already are deactivated, and by, as when starting up the circuit arrangement, with deactivated actuators P1, P2,. , , Pn is the DC supply voltage U0 by closing the supply switch SW0 to the output terminal N0 is placed and the discharge switch SW2 is actuated until the operating chip UC has reached the desired value. The circuit arrangement acts in these time intervals also as a step-up converter, with which the between the off Span connection N0 and the voltage supply connection N1 voltage in the operating voltage UC applied to the storage capacitor C0 is set. The voltage to be stepped up is now not as with the discharge that of an actuator from this actuator but from an additional energy source, the DC voltage source V0 provided.

The main advantage of the circuit arrangement according to the invention is thus in that both when loading and unloading the actuators and when charging and recharging the storage capacitor C0 the same coil L as an inductive construction element is used.

In the present exemplary embodiment, the circuit arrangement is used for control several actuators P1, P2,. , , Pn used; however, of course it is  conceivable to use the circuit arrangement for controlling a single actuator put.

Claims (12)

1. A method for controlling at least one capacitive actuator (P1, P2,... Pn) which is charged during a charging process by repeatedly actuating a charging switch (SW1) via an inductive component (L) or during a discharging process by repeatedly actuating a discharging switch (SW2) is discharged via the inductive component (L), with charge being removed from a storage capacitor (C0) during the charging process and charging being supplied to the storage capacitor (C0) during the discharging process, characterized in that a DC supply voltage ( U0) with deactivated actuator (P1) or deactivated actuators (P1, P2,... Pn) is applied to a connection (N0) of the inductive component (L) and the storage capacitor (C0) through the inductive component (L) repeated actuation of the discharge switch (SW2) is loaded. 2. The method according to claim 1, characterized in that the storage condenser gate (C0) in repeating time intervals to a given operating span voltage (UC) is loaded. 3. The method according to claim 1 or 2, characterized in that one by the Actuator (P1) or current path leading through one of the actuators (P1, P2,... Pn) interrupted to deactivate this actuator. 4. The method according to any one of the preceding claims, characterized in that when controlling several actuators (P1, P2,... Pn) at most one of the actuators is activated simultaneously for loading or unloading. 5. The method according to any one of the preceding claims, characterized in that the actuator (P1) or each of the actuators (P1, P2, ... Pn) only after completion of the charging or discharging process is released for deactivation.   6. Circuit arrangement for performing the method according to one of the previous gene claims, characterized in that the actuator (P1) or each of Actuators (P1, P2,... Pn) is connected to an output connection (N0), where the output connection (N0) via the inductive component (L) with a scarf tion node (N3) is connected, the circuit node (N3) via the charging switch (SW1) and a first diode (D1) connected in parallel with the memory con capacitor (C0) is connected as well as via the discharge switch (SW2) and one second diode (D2) connected in parallel with a voltage supply connection (N1) is connected, and that the actuator (P1) to activate or deactivate it a selection switch (S1) is assigned or the actuators (P1, P2,... Pn) a selection switch (S1, S2,... Sn) is assigned. 7. Circuit arrangement according to claim 6, characterized in that each Actuator (P1, P2,... Pn) in an the output terminal (N0) with the voltage supply connection (N1) connecting current branch for assigned selection switch (S1, S2,... Sn) is connected in series. 8. Circuit arrangement according to claim 6 or 7, characterized in that a DC voltage source (V) that can be connected via a supply switch (SW0) to apply the DC supply voltage (U0) to the output connection (N0) is provided. 9. Circuit arrangement according to one of claims 6 to 8, characterized in net that each actuator (P1, P2, ... Pn) is designed as a piezoelectric element. 10. Circuit arrangement according to one of claims 6 to 9, characterized in net that the voltage supply connection (N1) is at a reference potential. 11. Circuit arrangement according to one of claims 6 to 10, characterized records that the inductive component (L) is designed as a coil. 12. Use of the circuit arrangement according to one of claims 6 to 11 for Control of actuators (P1, P2, ... Pn) in injectors for fuel di direct injection in internal combustion engines.