DE10022954A1 - Control circuit for controlling at least one solenoid valve for metering fuel in an internal combustion engine - Google Patents

Abstract

According to the invention, a control circuit for controlling solenoid valves for fuel metering in an internal combustion engine (banks I and II) has a recharging circuit (1) which has a choke coil (110) in series with a diode (112) and a storage capacitor (145) and a parallel circuit for the series connection of diode (112) with the storage capacitor (145) connected FET power transistor (113). The solenoid valves of the individual banks (I and II) are only activated with a pre-stabilized voltage generated by the recharging circuit (1), which can cover a wide range, the battery voltage (U¶BAT¶) can fall short or exceed, so that the HS and booster switches known from previous circuits can be implemented in a single switch (FIG. 2).

Description

State of the art

The invention relates to a control circuit for Control of at least one solenoid valve for the Fuel metering in an internal combustion engine according to the Preamble of claim 1.

Such a control circuit is such. B. from the German Patent application 195 39 071 of Robert Bosch GmbH known. With this known control circuit, fast Solenoid valves e.g. B. for "common rail injection" or "Direct petrol injection" from internal combustion engines Booster and battery supply voltage FET switches controlled, which at the transition from the starting current to the holding current released energy in a capacitor is saved.

This circuit arrangement requires a variety of Components and complex driver circuits that it allow the valves to be controlled with large flows heading for. The resulting ones are disadvantageous Dependencies of the switch-off edges for quick extinguishing of the solenoid valves from the battery voltage.

New developments in fast solenoid valves allow one  Reduction of the control current and thus that for the Control of the solenoid valves required energy.

Object and advantages of the invention

It is an object of the invention to provide a control circuit for Control of at least one solenoid valve for the Fuel metering in an internal combustion engine so too enable the shutdown edges at the Quick delete largely independent of changes in Battery voltage are the usable operating range of the Control circuit is expanded and that for generation of the drive current necessary energy can be reduced.

This task is solved according to the requirements.

The core of the control circuit according to the invention is a Recharge circuit that with the first and second connection the supply voltage to generate a pre-stabilized recharge voltage for the Storage capacitor from the battery supply voltage and is connected to the first switching means and the Contains storage capacitor and a third switching means, that, driven by the control means, the Recharge circuit for recharging the storage capacitor activated.

It is therefore possible to use the fast solenoid valves exclusively with the by the recharge circuit to generate generated, pre-stabilized voltage.

The pre-stabilized voltage can have a wide range include that under or the battery voltage can exceed.

The second HS- known from today's control circuits  Switches per bank with associated, other components omitted without replacement.

The capacitors on the battery voltage are less stressed because of a current switch between different current branches is eliminated.

The dependence of the solenoid valve control on Changes in battery voltage are largely eliminated. The usable operating area is thus expanded and is regardless of the vehicle electrical system voltage.

An embodiment of the invention is described with reference to FIG the drawing is explained in more detail below.

drawing

Fig. 1 shows graphically a current curve over time when driving a solenoid valve with the control circuit according to the invention and

Fig. 2 is a circuit diagram schematically showing an embodiment of a drive circuit according to the invention.

Embodiment

First, FIG. 1 illustrates graphically the timing of the current I (in amps) thereof by a solenoid valve during a driving operation. First, the control circuit according to the invention carries out a starting current control AR during a starting phase at a relatively high starting current. The booster phase is omitted because it is combined with the tightening phase. This is followed by a reduction in the current to the holding current, which is less than the starting current. During the holding phase, the control circuit according to the invention carries out a holding current regulation HR. Then there is a quick erase SL to the current level 0.

Fig. 2 is a block diagram of a drive circuit according to the invention shows an example for two banks I and II.

The bank I contains, for example, three solenoid valves 100 , 101 and 102 , which are interconnected with their high-side ends and are supplied with current from the recharge circuit 1 via an HS-FET (high-side field-effect transistor) 115 . The other ends of the solenoid valves 100 , 101 , 102 are each connected to the recharging circuit 1 via diodes and each via an LS-FET (low-side field effect transistor) 120 , 121 , 122 and a measuring resistor R1 to a ground connection GND of the battery _{supply voltage} U _BATT .

The recharge circuit 1 proposed _{according to the invention has} a choke coil 110 , a diode 112 , a storage capacitor 145 , a measuring resistor 111 and, parallel to the series connection of the diode 112 with the storage capacitor 145 , between a first connection U _BR and the second connection GND of the battery _{supply voltage} U _BATT . a field effect transistor 113 .

It can be seen that the circuit of the second bank II is identical to that of the first bank I and that the recharging circuit 1 is common to both banks I and II. The control connections of the HS-FETs 115 , 116 and the LS-FETs 120 , 121 , 122 and 220 , 221 and 222 of both banks I and II are connected to driver circuits 10 and 11 (control means) by control lines (not shown).

The function of the drive circuit shown in Fig. 2 is as follows. The solenoid valves 100 , 101 , 102 of bank I and 200 , 201 , 202 of bank II to be controlled are each selected via the corresponding LS-FET 120 , 121 , 122 or 220 , 221 , 222 . The HS-FET 115 , 116 of the respective bank I, II controls the current profile during the pull-in and hold phase with the pre-stabilized recharge voltage generated by the recharge circuit 1 . The booster phase of previous control circuits is omitted because it is combined with the starting current phase. Thus, the solenoid valves of the individual banks I, II are controlled exclusively with the pre-stabilized voltage generated by the recharging circuit 1 .

The transitions from the pull-in phase to the hold phase are created in the event of a transition by rapid extinction by switching off the respective LS-FET and HS-FET or simply as a freewheeling operation by switching off the respective LS-FET or HS-FET. The respective solenoid valve is switched off via quick extinguishing (SL in FIG. 1) with the LS-FET and HS-FET switched off. During the quick-erase SL, energy is returned to the storage capacitor 145 via the quick-erase diodes of the respective bank I, II.

The recharging circuit 1 either clocks continuously and / or is regulated accordingly when the desired voltage is reached. A resistor 111 , which is connected in series between the storage capacitor 145 and the second connection GND of the supply voltage U _BATT , is used to measure the voltage at the storage capacitor. The "hot" end of the measuring resistor 111 is connected to the driver circuit 11 or the control means. The driver circuit 11 is connected to a higher-level control unit (not shown) via a line system.

The recharging circuit 1 proposed according to the invention enables the generation of a pre-stabilized voltage with which all the solenoid valves can be controlled in the pull-in and hold phase. The pre-stabilized voltage can cover a wide range, which can _fall below or exceed the battery _voltage U _BATT . The capacitors located at the battery _voltage U _BATT , which are symbolized in FIG. 2 by a capacitance C, are less stressed, since there is no current switching between different current branches. Because the control circuit according to the invention avoids the dependence of the control currents on the battery voltage, the usable operating range can be expanded.

Claims (9)

1. Circuit arrangement for controlling at least one kneading valve for fuel metering in an internal combustion engine, with first switching means ( 115 , 116 ), which are connected to a first connection of the at least one solenoid valve ( 100 , 101 , 102 ; 200 , 201 , 202 ), the second Switching means ( 120 , 121 , 122 ; 220 , 221 , 222 ), each between a second connection of an associated solenoid valve ( 100 , 101 , 102 ; 200 , 201 , 202 ) and the second connection (GND) of the supply voltage (U _BATT ) are arranged, and with control means ( 10 , 11 ) which control the switching means in such a way that during the rapid transition from a starting current value (I _A ) to a holding current value (I _H ) or from a holding current value (I _H ) to current 0 is released Energy can be stored in a storage capacitor ( 145 ) connected to a respective second connection of the solenoid valve or the solenoid valves and the solenoid valve (s) in its activation phase can be supplied again, characterized in that a recharging circuit ( 110 , 111 , 112 , 113 , 145 ) with the first and second connection (U _BR , GND) of the supply voltage (U _BATT ) for generating a pre-stabilized recharging voltage for the storage capacitor ( 145 ) from the battery _{supply voltage} (U _BATT ) and connected to the first switching means ( 115 , 116 ), the recharging circuit containing the storage capacitor ( 145 ) and a third switching means ( 113 ) which, controlled by the control means ( 10 , 11 ), the Reload circuit for recharging the storage capacitor ( 145 ) activated. 2. Control circuit according to claim 1, characterized in that the control means ( 10 , 11 ) are set up so that they clock the third switching means ( 113 ) continuously. 3. Control circuit according to claim 1, characterized in that the recharging circuit further comprises measuring means ( 111 ) which supply a voltage value measured at the storage capacitor ( 145 ) to the control means ( 10 , 11 ), the control means ( 10 , 11 ) providing the third switching means ( 113 ) to recharge the storage capacitor ( 145 ) only if the detected voltage across the storage capacitor ( 145 ) falls below a certain setpoint. 4. Control circuit according to claim 3, characterized in that the measuring means ( 111 ) have a resistor which is connected in series between the storage capacitor ( 145 ) and the second terminal (GND) of the supply voltage (U _BATT ). 5. Control circuit according to one of claims 1-4, characterized in that the recharging circuit further comprises a choke coil ( 110 ) connected in series with the storage capacitor ( 145 ) and a diode ( 112 ) which is connected in series between the choke coil ( 110 ) and the Storage capacitor ( 145 ) is connected, and that a connection point of the diode ( 112 ) with the storage capacitor ( 145 ) is connected to the second connection or connections of the solenoid valve or the solenoid valves. 6. Control circuit according to one of the preceding claims, characterized in that the third switching means ( 113 ) is connected in parallel to the series connection of the diode ( 112 ) with the storage capacitor ( 145 ). 7. Control circuit according to one of the preceding Claims, characterized in that the switching means FET power switching transistors or the like. 8. Control circuit according to one of the preceding Claims, characterized in that the solenoid valves and the first and second switching means in multiple banks (I, II) are grouped, with each bank having one or more Solenoid valves, a FET power switching transistor as first switching means and one or more FET Power switching transistors, each of which Solenoid valves are assigned as second switching means exhibit. 9. Control circuit according to claim 8, characterized in that the ends of the second switching means of each bank facing away from the solenoid valves are individually connected together and connected together to one end of a measuring resistor (R1, R2), the other end of which is connected to the second connection (GND). the supply voltage (U _BATT ) is connected, and that a voltage value can be tapped at the respective end of these measuring resistors connected to the second switching means and can be supplied to the control means ( 10 , 11 ).